A tubular conveyance system includes a pressure sensor, a blower, a material feeder, and a flow control apparatus. The pressure sensor is configured to be associated with a conveyance tube. The blower is configured to accelerate a carrier fluid into the conveyance tube. The material feeder is disposed downstream of the blower and configured to add a conveyance material to the conveyance tube to be conveyed by the carrier fluid. The flow control apparatus is configured to control an amount of carrier fluid provided to the blower. The flow control apparatus includes a mobile plate having a mobile plate opening therein, and a drive mechanism configured to selectively place the mobile plate into an open position and a closed position.

A mechanically-controlled vacuum throttle for a continuous dense phase pneumatic conveying system and related method is provided. The system includes a pneumatic conveyance line, a particulate material insertion assembly, a positive displacement blower, a transport fluid intake assembly, and a vacuum throttling assembly. The vacuum throttling assembly is configured to control the flow of air mass density into the blower and through the conveyance line. A portion of the vacuum throttling assembly is tied in to the conveyance line pressure downstream of the blower and adjusts the air mass density flow depending on the downstream pressure. Preferably, the vacuum throttling assembly includes an obstruction element and an opening collar, where the obstruction element is moveable relative to the opening collar and the air mass density flow is adjusted depending on the amount of movement of the obstruction element relative to the opening collar.

A process and device for controlled feeding of incoherent solid materials for differentiated pressure systems along a pipeline through the pressure of a fluid in the gaseous state. The pipeline is obtained by combining a plurality of consecutive trunk sections. The device includes a mechanism for intermittent feeding of the incoherent solid material in the pipeline, a mechanism for feeding the gaseous fluid under pressure in a plurality of predefined feeding points of the pipeline, a first series of valve members applied to each trunk section for intercepting the pipeline under control, a second series of valve members applied to each trunk section for allowing the escape of the expanded gaseous fluid from the pipeline and centralized control for closing the first series of valve members and for the concurrent opening of the second series of valve members. The feeding mechanism for the gaseous fluid under pressure can introduce the gaseous fluid under pressure in each feeding point of the pipeline when the first valve members located upstream of the feeding point are closed and the first valve members located downstream are open, and when the second valve members located upstream of the feeding point are open and the second valve members located downstream are closed.