Developed to transport any products, whether industrialized or not, via streams, in different geographic regions. By means of a piping circuit (1) housing distributing stations (3), in suitable points in the region of installation are formed streams driven by hydraulic pumps (2) successively installed along the length of such circuit (1). The streams are provided with conveyor capsules (4) of any industrial objects or not, capable of being carried by these capsules (4). In this way, the piping circuit (1) can be installed so as to cover large a geographic area and, for its internal rapids, to promote the transport of goods of all kinds. For control on delivery, upon stop at the predefined distribution station (3), the corresponding conveying capsule (4) shall be identified by its electronic registration. These capsules (4), after being unloaded at their distribution stations (3), are returned to the circulation by the circuit (1) and so on, thus forming an unprecedented supply system for large geographical regions.

Developed to transport any products, whether industrialized or not, via streams, in different geographic regions. By means of a piping circuit (1) housing distributing stations (3), in suitable points in the region of installation are formed streams driven by hydraulic pumps (2) successively installed along the length of such circuit (1). The streams are provided with conveyor capsules (4) of any industrial objects or not, capable of being carried by these capsules (4). In this way, the piping circuit (1) can be installed so as to cover large a geographic area and, for its internal rapids, to promote the transport of goods of all kinds. For control on delivery, upon stop at the predefined distribution station (3), the corresponding conveying capsule (4) shall be identified by its electronic registration. These capsules (4), after being unloaded at their distribution stations (3), are returned to the circulation by the circuit (1) and so on, thus forming an unprecedented supply system for large geographical regions.

Developed to transport any products, whether industrialized or not, via streams, in different geographic regions. By means of a piping circuit (1) housing distributing stations (3), in suitable points in the region of installation are formed streams driven by hydraulic pumps (2) successively installed along the length of such circuit (1). The streams are provided with conveyor capsules (4) of any industrial objects or not, capable of being carried by these capsules (4). In this way, the piping circuit (1) can be installed so as to cover large a geographic area and, for its internal rapids, to promote the transport of goods of all kinds. For control on delivery, upon stop at the predefined distribution station (3), the corresponding conveying capsule (4) shall be identified by its electronic registration. These capsules (4), after being unloaded at their distribution stations (3), are returned to the circulation by the circuit (1) and so on, thus forming an unprecedented supply system for large geographical regions.

A pneumatic transport system for histological samples includes a transport tube within which a carrier containing samples is transported. A station for loading/unloading the samples into/from the carrier is arranged at one tube end. When the carrier is arriving at the station, a blower of the system is deactivated and the carrier is braked, allowing stopping within the station against a stop member. Thereafter, a motor imparts, via the stop member, rotation to said carrier until a carrier door is at an angular position substantially corresponding to an angular position of a station door. Thereafter, the carrier is stopped and the doors are opened by an actuator, this enabling activation of an operating cycle of loading/unloading of the samples. Upon completion, the doors are closed, a carrier locking device is deactivated and the blower is activated, allowing departure of the carrier from the station and its transport within the tube.

A pneumatic transport system for histological samples includes a transport tube within which a carrier containing samples is transported. A station for loading/unloading the samples into/from the carrier is arranged at one tube end. When the carrier is arriving at the station, a blower of the system is deactivated and the carrier is braked, allowing stopping within the station against a stop member. Thereafter, a motor imparts, via the stop member, rotation to said carrier until a carrier door is at an angular position substantially corresponding to an angular position of a station door. Thereafter, the carrier is stopped and the doors are opened by an actuator, this enabling activation of an operating cycle of loading/unloading of the samples. Upon completion, the doors are closed, a carrier locking device is deactivated and the blower is activated, allowing departure of the carrier from the station and its transport within the tube.

A system, apparatus and method (i.e., utility) is provided for increasing the resource utilization of a pneumatic tube system (PTS). This utility allows for moving two or more carriers during a single air source cycle. That is, air pressure or vacuum during a single cycle of an air source may be utilized to move multiple carriers and thereby reduce the total number of cycles required to complete two or more transactions. Accordingly, the throughput of the PTS may be increased.

A system, apparatus and method (i.e., utility) is provided for increasing the resource utilization of a pneumatic tube system (PTS). This utility allows for moving two or more carriers during a single air source cycle. That is, air pressure or vacuum during a single cycle of an air source may be utilized to move multiple carriers and thereby reduce the total number of cycles required to complete two or more transactions. Accordingly, the throughput of the PTS may be increased.

A pneumatic transport system for organic samples includes a transport tube within which a carrier containing samples is transported. A station for loading/unloading the samples into/from the carrier is arranged at one tube end. When the carrier is arriving at the station, a blower of the system is deactivated and the carrier is braked, allowing stopping within the station against a stop member. Thereafter, a motor imparts, via the stop member, rotation to said carrier until a carrier door is at an angular position substantially corresponding to an angular position of a station door. Thereafter, the carrier is stopped and the doors are opened by an actuator, this enabling activation of an operating cycle of loading/unloading of the samples. Upon completion, the doors are closed, a carrier locking device is deactivated and the blower is activated, allowing departure of the carrier from the station and its transport within the tube.

A pneumatic transport system for organic samples includes a transport tube within which a carrier containing samples is transported. A station for loading/unloading the samples into/from the carrier is arranged at one tube end. When the carrier is arriving at the station, a blower of the system is deactivated and the carrier is braked, allowing stopping within the station against a stop member. Thereafter, a motor imparts, via the stop member, rotation to said carrier until a carrier door is at an angular position substantially corresponding to an angular position of a station door. Thereafter, the carrier is stopped and the doors are opened by an actuator, this enabling activation of an operating cycle of loading/unloading of the samples. Upon completion, the doors are closed, a carrier locking device is deactivated and the blower is activated, allowing departure of the carrier from the station and its transport within the tube.

A carrier vault for a workstation of a pneumatic tube system includes a rotatable carousel comprising at least a first and second carrier port, each carrier port sized and shaped to hold a carrier used to transport materials via the pneumatic tube system and to allow the carrier to pass through the carousel. The carousel is configured to rotate between a first position, where the first carrier port is aligned with an access tube of the pneumatic tube system and a second position, where the second carrier port is aligned with the access tube. The carrier vault further comprises a selection gate adjacent to the carousel comprising a rotatable plate and a selection gate opening. The selection gate is configured to rotate between an open position, where the carrier is allowed to pass through the plate, and a closed position, where the carrier is prevented from passing through the plate.