A system (1) dispenses dosages of a powdery substance. It has a robotic handler (2), a weighing module (8) with a weighing pan (9), at least one storage rack (4) for holding a plurality of dispensing heads (3) and at least one storage rack (6) for holding a plurality of vials (5), a dosage dispenser unit (11) with a dispensing head receiver (12), a vial handling tool (17) and a dispensing head handling tool (18), a tool-docking station (19) for the handling tools, and a controller terminal unit (20). Different weighing pan adapters (15) adapt the weighing pan to different shapes and sizes of vials. Relative to a vertical working orientation, tlower portions of the weighing pan adapters are identical, to fit the weighing pan, but upper portions are different, to accommodate different shapes and sizes of vials. A station (16) is provided for storing the weighing pan adapters.

A system (1) dispenses dosages of a powdery substance. It has a robotic handler (2), a weighing module (8) with a weighing pan (9), at least one storage rack (4) for holding a plurality of dispensing heads (3) and at least one storage rack (6) for holding a plurality of vials (5), a dosage dispenser unit (11) with a dispensing head receiver (12), a vial handling tool (17) and a dispensing head handling tool (18), a tool-docking station (19) for the handling tools, and a controller terminal unit (20). Different weighing pan adapters (15) adapt the weighing pan to different shapes and sizes of vials. Relative to a vertical working orientation, tlower portions of the weighing pan adapters are identical, to fit the weighing pan, but upper portions are different, to accommodate different shapes and sizes of vials. A station (16) is provided for storing the weighing pan adapters.

A ship loading system for loading fluidizable materials into a ship's hold is described. The system comprises a self-supporting tubular boom that is attached to a support tower at a single attachment point. An air gravity conveyor is enclosed within the tubular boom for materials from the vicinity of the support tower to the ship's hold.

Disclosed is a system for conveying particulate material, in which particulate material is conveyed along a conveying pipeline (117) by a flow of a conveying gas. A plurality of injector arrangements (121) are positioned along the conveying pipeline, for injecting a continuous flow of conveying gas into the pipeline. The system includes pressure differential apparatus for detecting whether a pressure differential in the pipeline between an injector arrangement and an adjacent injector arrangement is above or below a threshold value. In use each injector arrangement is operable to increase the flow rate at which conveying gas is injected into the pipeline when a pressure differential rises above the threshold value is detected between adjacent injection locations along the pipeline. The present invention provides a continuous flow of conveying gas at each of the plurality of injector arrangements, reducing the risk of blockage. Pressure differentials along the conveying pipeline are reduced. Together this facilitates stable and predictable conveying of the particulate material and reduced conveying gas usage.

This powder transport device comprises: transport pipe (11) that can transport powder by way of gravity by having a prescribed angle of inclination; a porous plate (12) that is disposed along the transport pipe (11) so as to divide a line cross section into a top section and bottom section and form a powder line (11d) in the top section; an inert gas supply line for fluidization (13) that is provided under the porous plate (12) and supplies an assist gas (g) to the powder line (11d) through the porous plate (12); and a deposit status monitoring device (20) that constantly monitors the state of the powder deposited on the top face side of the porous plate (12) in the powder line (11d).

This powder transport device comprises: transport pipe (11) that can transport powder by way of gravity by having a prescribed angle of inclination; a porous plate (12) that is disposed along the transport pipe (11) so as to divide a line cross section into a top section and bottom section and form a powder line (11d) in the top section; an inert gas supply line for fluidization (13) that is provided under the porous plate (12) and supplies an assist gas (g) to the powder line (11d) through the porous plate (12); and a deposit status monitoring device (20) that constantly monitors the state of the powder deposited on the top face side of the porous plate (12) in the powder line (11d).

A system (1) dispenses dosages of a powdery substance. It has a robotic handler (2), a weighing module (8) with a weighing pan (9), at least one storage rack (4) for holding a plurality of dispensing heads (3) and at least one storage rack (6) for holding a plurality of vials (5), a dosage dispenser unit (11) with a dispensing head receiver (12), a vial handling tool (17) and a dispensing head handling tool (18), a tool-docking station (19) for the handling tools, and a controller terminal unit (20). Different weighing pan adapters (15) adapt the weighing pan to different shapes and sizes of vials. Relative to a vertical working orientation, tlower portions of the weighing pan adapaters are identical, to fit the weighing pan, but upper portions are different, to accommodate different shapes and sizes of vials. A station (16) is provided for storing the weighing pan adapters.

A system (1) dispenses dosages of a powdery substance. It has a robotic handler (2), a weighing module (8) with a weighing pan (9), at least one storage rack (4) for holding a plurality of dispensing heads (3) and at least one storage rack (6) for holding a plurality of vials (5), a dosage dispenser unit (11) with a dispensing head receiver (12), a vial handling tool (17) and a dispensing head handling tool (18), a tool-docking station (19) for the handling tools, and a controller terminal unit (20). Different weighing pan adapters (15) adapt the weighing pan to different shapes and sizes of vials. Relative to a vertical working orientation, tlower portions of the weighing pan adapaters are identical, to fit the weighing pan, but upper portions are different, to accommodate different shapes and sizes of vials. A station (16) is provided for storing the weighing pan adapters.

A ship loading system for loading fluidizable materials into a ship's hold is described. The system comprises a self-supporting tubular boom that is attached to a support tower at a single attachment point. An air gravity conveyor is enclosed within the tubular boom for materials from the vicinity of the support tower to the ship's hold.

An apparatus (1) for conveying polyolefin particles, particularly foamed polyolefin particles, from a first location (L1) to a second location (L2), the apparatus (1) comprising: a pressurizing unit (2) for generating a pressurized particle conveying fluid stream, particularly comprising polyolefin particles in a pressurized fluid, the pressurized particle conveying fluid stream having a first pressure level; a decompressing unit (3) for decompressing the pressurized particle conveying fluid stream from the first pressure level to generate a decompressed particle conveying fluid stream having a second pressure level, wherein the decompressing unit (3) comprises: a first chamber (6) for receiving the pressurized particle conveying fluid stream and a second chamber (7) surrounding the first chamber (6), wherein the first chamber (6) is delimited by a first wall structure (6.1) and the second chamber (7) is delimited by a second wall structure (7.1); wherein the first wall structure comprises (6.1) at least one first opening (6.1.1) through which an inner volume of the first chamber (6) is connected with an inner volume of the second chamber (7) and the second wall structure (7.1) comprises at least one second opening (7.1) through which the inner volume of the second chamber (7) is connectable or connected with at least one dampening device (8).