A device (1) for feeding a processing device with powdery material (2) comprises a first chamber (3) having at least one fluidizing device (5) configured to fluidize and/or to potentially fluidize the powdery material (2), at least one second chamber (6) being in connection with the first chamber (3) such that fluidized and/or potentially fluidized powdery material (2) is transportable from the first chamber (3) into the second chamber (6), and at least one third chamber (9) being in connection with the second chamber (6) such, that the potentially fluidized powdery material (2) is transportable from the second chamber (6) into the third chamber (9). The device (1) is configured to defluidize the powdery material (2) such that it is present as defluidized powdery material (2) in the third chamber (9). The third chamber (9) has a discharge element (10) configured to discharge the defluidized powdery material (2).

A device (1) for feeding a processing device with powdery material (2) comprises a first chamber (3) having at least one fluidizing device (5) configured to fluidize and/or to potentially fluidize the powdery material (2), at least one second chamber (6) being in connection with the first chamber (3) such that fluidized and/or potentially fluidized powdery material (2) is transportable from the first chamber (3) into the second chamber (6), and at least one third chamber (9) being in connection with the second chamber (6) such, that the potentially fluidized powdery material (2) is transportable from the second chamber (6) into the third chamber (9). The device (1) is configured to defluidize the powdery material (2) such that it is present as defluidized powdery material (2) in the third chamber (9). The third chamber (9) has a discharge element (10) configured to discharge the defluidized powdery material (2).

A glove collecting device includes a guiding member including an internal space, an inlet at one end, and an outlet at the other end, wherein the end adjacent to the inlet of the guiding member is bent inwards such that the end adjacent to the inlet extends from the inlet towards the outlet to form an interlayer and the interlayer includes a plurality of holes; and an adaptor member disposed externally of the outlet and including a hollow connector distal the outlet, and a channel through the connector for communicating with the space of the guiding member.

A char removal pipe including a removal pipe (22), a perforated plate (26) that partitions the interior of the removal pipe (22) into a powder channel (29) and a gas chamber (30), and an assist gas supplying device (28) that supplies an assist gas to the gas chamber (30). The perforated plate (26) is formed so that the pressure loss when the assist gas flows from the gas chamber (30) to the powder channel (29) through the perforated plate (26) is greater than the pressure loss when the assist gas flows through accumulated powder formed by the accumulation, on the perforated plate (26), of powder flowing in the powder channel (29).

A char removal pipe including a removal pipe (22), a perforated plate (26) that partitions the interior of the removal pipe (22) into a powder channel (29) and a gas chamber (30), and an assist gas supplying device (28) that supplies an assist gas to the gas chamber (30). The perforated plate (26) is formed so that the pressure loss when the assist gas flows from the gas chamber (30) to the powder channel (29) through the perforated plate (26) is greater than the pressure loss when the assist gas flows through accumulated powder formed by the accumulation, on the perforated plate (26), of powder flowing in the powder channel (29).

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 device (1) for feeding a processing device with powdery material (2) comprises a first chamber (3) having at least one fluidizing device (5) configured to fluidize and/or to potentially fluidize the powdery material (2), at least one second chamber (6) being in connection with the first chamber (3) such that fluidized and/or potentially fluidized powdery material (2) is transportable from the first chamber (3) into the second chamber (6), and at least one third chamber (9) being in connection with the second chamber (6) such, that the potentially fluidized powdery material (2) is transportable from the second chamber (6) into the third chamber (9). The device (1) is configured to defluidize the powdery material (2) such that it is present as defluidized powdery material (2) in the third chamber (9). The third chamber (9) has a discharge element (10) configured to discharge the defluidized powdery material (2).

A device (1) for feeding a processing device with powdery material (2) comprises a first chamber (3) having at least one fluidizing device (5) configured to fluidize and/or to potentially fluidize the powdery material (2), at least one second chamber (6) being in connection with the first chamber (3) such that fluidized and/or potentially fluidized powdery material (2) is transportable from the first chamber (3) into the second chamber (6), and at least one third chamber (9) being in connection with the second chamber (6) such, that the potentially fluidized powdery material (2) is transportable from the second chamber (6) into the third chamber (9). The device (1) is configured to defluidize the powdery material (2) such that it is present as defluidized powdery material (2) in the third chamber (9). The third chamber (9) has a discharge element (10) configured to discharge the defluidized powdery material (2).

A mass-flow hopper that stores solid particulates and provides gas assistance to readily discharge the particulate matter. The mass flow hopper has an upper conical section connected via an intermediate section to a lower conical section having a lower discharge orifice. The lower conical section has a frustoconical configured gas impermeable wall lined with a gas permeable fluidizing plate spaced therefrom to define a lower space. The upper conical section slope is steeper than the lower frusto-conically configured gas permeable wall slope. Gas injected into the lower space passes from the lower space through the gas permeable fluidizing plate into the hopper to form a fluidized layer of gas between the solid particulates in the hopper and the gas permeable fluidizing plate. The fluidized layer of gas reduces wall friction within the lower conical section to facilitate discharging the particulates from the hopper.

A mass-flow hopper that stores solid particulates and provides gas assistance to readily discharge the particulate matter. The mass flow hopper has an upper conical section connected via an intermediate section to a lower conical section having a lower discharge orifice. The lower conical section has a frustoconical configured gas impermeable wall lined with a gas permeable fluidizing plate spaced therefrom to define a lower space. The upper conical section slope is steeper than the lower frusto-conically configured gas permeable wall slope. Gas injected into the lower space passes from the lower space through the gas permeable fluidizing plate into the hopper to form a fluidized layer of gas between the solid particulates in the hopper and the gas permeable fluidizing plate. The fluidized layer of gas reduces wall friction within the lower conical section to facilitate discharging the particulates from the hopper.