A pneumatic conveyor is operable to convey fine material and includes a pressure vessel and a pneumatic injection port. The pressure vessel presents a chamber operable to receive fine material and to be selectively pressurized with air to pressurize and convey the fine material. The pressure vessel includes an inclined wall that extends upwardly relative to an outlet, with fine material in the chamber being collected by the inclined wall and urged toward the outlet. The injection port fluidly communicates with the chamber, with the injection port located adjacent the outlet to inject compressed air into the flow of pressurized fine material.

A pneumatic conveyor is operable to convey fine material and includes a pressure vessel and a pneumatic injection port. The pressure vessel presents a chamber operable to receive fine material and to be selectively pressurized with air to pressurize and convey the fine material. The pressure vessel includes an inclined wall that extends upwardly relative to an outlet, with fine material in the chamber being collected by the inclined wall and urged toward the outlet. The injection port fluidly communicates with the chamber, with the injection port located adjacent the outlet to inject compressed air into the flow of pressurized fine material.

A robotic processing system and method are disclosed for processing materials using a series of containers stored in an automated storage and picking system. Each of the containers performs a specific function on the materials stored therein. The materials are passed from bin to bin via a suitable dispensing and transferring system. For example, a system is disclosed for delivering ingredients to a micro-brewery, as are methods for brewing small or test batches of beer according to customers' individual requirements.

A robotic processing system and method are disclosed for processing materials using a series of containers stored in an automated storage and picking system. Each of the containers performs a specific function on the materials stored therein. The materials are passed from bin to bin via a suitable dispensing and transferring system. For example, a system is disclosed for delivering ingredients to a micro-brewery, as are methods for brewing small or test batches of beer according to customers' individual requirements.

Assemblies, apparatuses, and methods to extract or convey a material from a source of the material may include a vacuum generation and sound attenuation assembly and a material receiver to enhance conveyance the material from the source of the material. The vacuum generation and sound attenuation assembly may include a vacuum source positioned to cause a vacuum flow between the source of the material, the material receiver, and the vacuum generation and sound attenuation assembly. The vacuum generation and sound attenuation assembly may further include a sound attenuation chamber positioned to receive at least a portion of the vacuum flow from, and attenuate sound generated by, the vacuum source. The material receiver may be positioned an elevated location relative to a source of the material and be capable of staging and metering the conveyance of material when moving material at the top of a structure, such as a refinery tower.

A hot melt adhesive supply system includes a container configured to receive a supply of unmelted hot melt adhesive pieces, and an agitation device configured to agitate the supply of hot melt adhesive pieces situated in the container. The hot melt adhesive supply system further includes a transfer conduit configured to communicate hot melt adhesive pieces from the container to a hot melt adhesive melter.

A hot melt adhesive supply system includes a container configured to receive a supply of unmelted hot melt adhesive pieces, and an agitation device configured to agitate the supply of hot melt adhesive pieces situated in the container. The hot melt adhesive supply system further includes a transfer conduit configured to communicate hot melt adhesive pieces from the container to a hot melt adhesive melter.

An arrangement for a pneumatic material conveying system comprising a first material conveying system. The arrangement comprises a second material conveying arrangement comprising at least one second input point (200) for feeding a second material (M), a second separator device (10), a second conveying pipe (102) between the at least one second:point (200) and the second separator device (10), which second separator device (10) is operatively connectable into medium communication with a conveying pipe (100) of the first material conveying system along the pipe, in order to connect a suction or a pressure difference acting in the first pipeline (100) to act via the second separator device (10) in the second conveying pipe (201) to convey the second material (M) from the second input point (200) in the second conveying pipe (201) to the second separator device (10) configured to separate the second material (M) from transporting air flow, and to collect the material (M) into a collection container (11) of the second separator device (10).

An arrangement for a pneumatic material conveying system comprising a first material conveying system. The arrangement comprises a second material conveying arrangement comprising at least one second input point (200) for feeding a second material (M), a second separator device (10), a second conveying pipe (102) between the at least one second:point (200) and the second separator device (10), which second separator device (10) is operatively connectable into medium communication with a conveying pipe (100) of the first material conveying system along the pipe, in order to connect a suction or a pressure difference acting in the first pipeline (100) to act via the second separator device (10) in the second conveying pipe (201) to convey the second material (M) from the second input point (200) in the second conveying pipe (201) to the second separator device (10) configured to separate the second material (M) from transporting air flow, and to collect the material (M) into a collection container (11) of the second separator device (10).

The present invention relates to a system for loading and unloading agents in the form of particulate solid material, used for carrying out a physical, chemical, and/or biological process in one or more tanks. The system includes: an intermediate tank, a pump, and a pneumatic conveyor. The intermediate tank and the pump are fluidically connected. For unloading a tank containing saturated or degraded solid material particles, an empty or partially empty solid material tank is fluidically connected to the intermediate tank and the tank containing saturated or degraded solid material particles. For loading a tank, a solid material tank containing unsaturated or undegraded solid material particles is fluidically connected to the intermediate tank.