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.

A fiber material storage device for a textile includes a storage chute having a chute housing and a supply line leading into the storage chamber. Fiber material is pneumatically conveyed with conveying air into the storage chamber. A cleaning unit in the storage chamber cleans contamination from the conveying air and includes a cleaning chamber. A semipermeable dividing wall is situated between the storage chamber and the cleaning chamber to retain the fiber material in the storage chamber and allow the contaminated conveying air to flow into the cleaning chamber. A filter element is situated in the conveying air flow between the cleaning chamber and outer surroundings to retain the contamination in the cleaning chamber and allow filtered conveying air to escape into the surroundings. The cleaning housing has a collection chamber situated underneath the cleaning chamber, wherein the contamination retained by the filter element settles in the collection chamber.

A fiber material storage device for a textile includes a storage chute having a chute housing and a supply line leading into the storage chamber. Fiber material is pneumatically conveyed with conveying air into the storage chamber. A cleaning unit in the storage chamber cleans contamination from the conveying air and includes a cleaning chamber. A semipermeable dividing wall is situated between the storage chamber and the cleaning chamber to retain the fiber material in the storage chamber and allow the contaminated conveying air to flow into the cleaning chamber. A filter element is situated in the conveying air flow between the cleaning chamber and outer surroundings to retain the contamination in the cleaning chamber and allow filtered conveying air to escape into the surroundings. The cleaning housing has a collection chamber situated underneath the cleaning chamber, wherein the contamination retained by the filter element settles in the collection chamber.

The present invention is a new apparatus to efficiently reclaim cement from a horizontal warehouse. This new reclaiming apparatus combines a mechanical cement reclaiming machine, a U Reclaimer Utility Device Apparatus, together with a reduced amount of open air slides, cement is pushed by a rotating chain with rakes on said reclaiming machine, cement is further fluidized through a porous media with low pressure air, cement flow is achieved by sloping said air slides to match the fluidized angle of repose of the powdered material. Further, the present invention introduces a conveying system, composed by a cascade of enclosed air slides and elevator machines, to convey the cement from the reclaiming area to the dispatch hopper. The introduction of these components, together with traditional cement stacking methods and dispatch systems, provides for a highly efficient manner of storing and reclaiming material from a horizontal storage facility.

A material application system includes a hopper assembly and a conveyor assembly. The hopper assembly includes an upper portion and a downcomer portion. Bulk material is loaded into the upper portion and passes through the downcomer portion. The downcomer portion may include a sail plate for agitating the bulk material to inhibit the formation of clogs in the bulk material.

A conveying system for conveying a conveyable material from a hopper where the system includes a fluid port located below the hopper outlet and in a vertical flow path into hopper outlet that can be momentarily opened for an on the go release of a charge of compressed air directly upward into the hopper outlet and into the underside of the bridge in the hopper to either disintegrate or unlock the bridged particles from each other thereby causing the bridged material to fall into the hopper outlet and into the conveying system where the material can be transported to a remote location or to remove any material that may be adhering to the wall during an emptying phase.

A conveying system for conveying a conveyable material from a hopper where the system includes a fluid port located below the hopper outlet and in a vertical flow path into hopper outlet that can be momentarily opened for an on the go release of a charge of compressed air directly upward into the hopper outlet and into the underside of the bridge in the hopper to either disintegrate or unlock the bridged particles from each other thereby causing the bridged material to fall into the hopper outlet and into the conveying system where the material can be transported to a remote location or to remove any material that may be adhering to the wall during an emptying phase.

A grain facility has a grain receiving station and a grain transport line with a grain elevator, a distributor with at least one input spout, and at least one grain bin. The grain transport line moves grain from the grain receiving station to one of the at least one grain bins and the distributor directs the grain to a selected bin of the at least one grain bin. The grain facility further includes an optical sensing system having at least one optical sensor positioned in the grain transport line at or before the distributor, wherein the optical sensing system senses the type of grain in the grain transport line. A control system determines if the grain passing through the grain transport line is suitable for the selected grain bin and produces an alarm if the grain in the grain transport line is not suitable for the selected grain bin.

A grain facility has a grain receiving station and a grain transport line with a grain elevator, a distributor with at least one input spout, and at least one grain bin. The grain transport line moves grain from the grain receiving station to one of the at least one grain bins and the distributor directs the grain to a selected bin of the at least one grain bin. The grain facility further includes an optical sensing system having at least one optical sensor positioned in the grain transport line at or before the distributor, wherein the optical sensing system senses the type of grain in the grain transport line. A control system determines if the grain passing through the grain transport line is suitable for the selected grain bin and produces an alarm if the grain in the grain transport line is not suitable for the selected grain bin.

A grain storehouse includes a granary, a grain loading system, and a grain unloading system. The granary includes multiple storages arranged in a network format. The bottom of each storage is a tapered structure with a tapered surface downward, and the bottom of the tapered structure provides a switchable blanking exit. The grain loading system includes a lattice girder structure, a plurality of conveyors and multiple hoppers. The grain unloading system includes at least one conveyor that is located under the blanking exit. The present invention improves the automaticity and efficiency of grain loading and unloading of the grain storehouse, so that the grain can be transferred quickly.