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.

The disclosure provides a system comprising one or more supply tanks; a central cement mixing unit; a support unit comprising a compressor and a power supply; a first valve disposed upstream of each of the one or more supply tanks; a second valve disposed downstream of each of the one or more supply tanks; a controller disposed at the central cement mixing unit; and a secondary controller disposed at each of the one or more supply tanks; wherein the one or more supply tanks are coupled to the central cement mixing unit, wherein the compressor is coupled to each of the one or more supply tanks, wherein the power supply is coupled to the compressor and to each of the one or more supply tanks, wherein the controller is communicatively coupled to each of the secondary controllers and to the support unit.

The disclosure provides a system comprising one or more supply tanks; a central cement mixing unit; a support unit comprising a compressor and a power supply; a first valve disposed upstream of each of the one or more supply tanks; a second valve disposed downstream of each of the one or more supply tanks; a controller disposed at the central cement mixing unit; and a secondary controller disposed at each of the one or more supply tanks; wherein the one or more supply tanks are coupled to the central cement mixing unit, wherein the compressor is coupled to each of the one or more supply tanks, wherein the power supply is coupled to the compressor and to each of the one or more supply tanks, wherein the controller is communicatively coupled to each of the secondary controllers and to the support unit.

A collapsible storage system for flowable material, for example granular material, includes a base frame and an upper frame which is movable between a collapsed position and a working position spaced above the collapsed position. A plurality of storage silos are supported in a row, each including a hopper discharge cone on the base frame and a collapsible tubular wall assembly connected between the discharge cone and the upper frame. Redundant loading conveyors are provided in communication with the silos across the upper frame for loading and redundant unloading conveyors are provided in communication with the silos across the base frame.

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.

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.

A storage apparatus for bulk material, in particular wood chips, is provided, the storage apparatus including a bunker for receiving the bulk material and a conveyor apparatus for transporting the bulk material. The conveyor apparatus is arranged within the bunker. The conveyor apparatus is a belt conveyor for transporting the bulk material. A method of controlling uniform filling of a bunker of a storage apparatus is also provided.

A storage apparatus for bulk material, in particular wood chips, is provided, the storage apparatus including a bunker for receiving the bulk material and a conveyor apparatus for transporting the bulk material. The conveyor apparatus is arranged within the bunker. The conveyor apparatus is a belt conveyor for transporting the bulk material. A method of controlling uniform filling of a bunker of a storage apparatus is also provided.

A transfer system for soft gels is disclosed. It comprises: a blower, having a first air inlet and a first air outlet, and generating an airflow by inhaling air from the first air inlet and discharging air out of the first air outlet; a hopper, having a top opening to catch soft gels manufactured and dropped directly from a soft gel machine and a bottom opening to drop the soft gels; a transfer hose, having a first opening connected to the first air outlet and a second opening, wherein a side-cut opening is formed to connect to the bottom opening, the airflow from the first opening blows the soft gels dropped at the side-cut opening to move the soft gels toward the second opening; a cooling module, having a second air inlet and a second air outlet, cooling down the external air from the second air inlet and discharging the cooled air from the second air outlet; and a connecting hose, connecting the second air outlet and the first air inlet.