Method for treating outlet air in a pneumatic waste conveying system, in which the outlet air is at least partly the conveying air to be used in waste conveying. In the method in a first phase additional air is brought into the body of conveying air in the partial-vacuum generator of the pneumatic waste conveying system before the output aperture of the partial-vacuum generator, and that in the method in a second phase additional air is brought into the body of outlet air as a consequence of the suction effect brought about by the outlet air in such a way that the outlet air and the additional air mix with each other at least partly. The invention also relates to an apparatus.

Method for treating outlet air in a pneumatic waste conveying system, in which the outlet air is at least partly the conveying air to be used in waste conveying. In the method in a first phase additional air is brought into the body of conveying air in the partial-vacuum generator of the pneumatic waste conveying system before the output aperture of the partial-vacuum generator, and that in the method in a second phase additional air is brought into the body of outlet air as a consequence of the suction effect brought about by the outlet air in such a way that the outlet air and the additional air mix with each other at least partly. The invention also relates to an apparatus.

A material conveying system, comprising: one or more material sources for providing material to be transferred; one or more destination locations for receiving material from the one or more material sources; one or more material conveying lines; one or more vacuum pumps wherein each vacuum pump is operatively connected to one or more of the one or more destination locations via one or more vacuum source lines; a sensor disposed on, in or near each of the one or more material conveying lines; a programmable electronic control unit (ECU) connected, via wires or wirelessly, to each component of the material conveying system including the one or more material sources, the one or more destination locations, the one or more vacuum pumps and to the one or more sensors; wherein the ECU uses data from the one or more sensors to (i) determine flow patterns and/or stream density of the material being conveyed through the one or more material conveying lines; and (ii) make automatic adjustments for optimizing and maintaining the material flow patterns in the one or more material conveying lines based on data provided by the one or more sensors.

A material conveying system, comprising: one or more material sources for providing material to be transferred; one or more destination locations for receiving material from the one or more material sources; one or more material conveying lines; one or more vacuum pumps wherein each vacuum pump is operatively connected to one or more of the one or more destination locations via one or more vacuum source lines; a sensor disposed on, in or near each of the one or more material conveying lines; a programmable electronic control unit (ECU) connected, via wires or wirelessly, to each component of the material conveying system including the one or more material sources, the one or more destination locations, the one or more vacuum pumps and to the one or more sensors; wherein the ECU uses data from the one or more sensors to (i) determine flow patterns and/or stream density of the material being conveyed through the one or more material conveying lines; and (ii) make automatic adjustments for optimizing and maintaining the material flow patterns in the one or more material conveying lines based on data provided by the one or more sensors.

A vacuum nozzle includes a main body and at least one auxiliary body. The main body has a first open end and a second open end. The first open end is coupleable to a vacuum hose and the second open end is configured for receiving materials to be transferred. The auxiliary body has a first auxiliary opening and a second auxiliary opening. The first auxiliary opening is positioned closer to the first open end of the main body than the second open end of the main body. The second auxiliary opening covers a portion of the second open end of the main body. The auxiliary body provides a dedicated auxiliary passageway for providing a consistent flow of air to the second open end of the main body when the vacuum nozzle is in use.

A vacuum nozzle includes a main body and at least one auxiliary body. The main body has a first open end and a second open end. The first open end is coupleable to a vacuum hose and the second open end is configured for receiving materials to be transferred. The auxiliary body has a first auxiliary opening and a second auxiliary opening. The first auxiliary opening is positioned closer to the first open end of the main body than the second open end of the main body. The second auxiliary opening covers a portion of the second open end of the main body. The auxiliary body provides a dedicated auxiliary passageway for providing a consistent flow of air to the second open end of the main body when the vacuum nozzle is in use.

Disclosed is a system for transferring fuel pellets from one container which may be at a location external to a building to a second container which may be at a location in an interior of the building. The system may include a first container positioned at a location remote from the building and a second container positioned proximate to the building. The first and second containers are connected to one another to permit the transfer of fuel pellets from the first container to the second container by a pneumatic apparatus.

Disclosed is a system for transferring fuel pellets from one container which may be at a location external to a building to a second container which may be at a location in an interior of the building. The system may include a first container positioned at a location remote from the building and a second container positioned proximate to the building. The first and second containers are connected to one another to permit the transfer of fuel pellets from the first container to the second container by a pneumatic apparatus.

A collection system for particulate matter along a conveyor system of products, which advance in an advancing direction, by means of a carrier gas flow; said collection system having a hood made by moulding of polymeric material; wherein the hood has a bent wall, which delimits a suction area, and a connection, which fluidly connects said suction area with a suction conduit through an opening of said bent wall; wherein said bent wall has a longitudinal axis, which in use is transversal, in particular perpendicular, to the advancing direction of the products.

A collection system for particulate matter along a conveyor system of products, which advance in an advancing direction, by means of a carrier gas flow; said collection system having a hood made by moulding of polymeric material; wherein the hood has a bent wall, which delimits a suction area, and a connection, which fluidly connects said suction area with a suction conduit through an opening of said bent wall; wherein said bent wall has a longitudinal axis, which in use is transversal, in particular perpendicular, to the advancing direction of the products.