A pneumatic tubing system for distribution of medical objects in a medical environment without a dedicated carrier. The system comprises a plurality of headwall stations, a sending or receiving station, at least one pump, and at least one controller. Each headwall station is adapted to be installed in a headwall structure proximate to a patient bedside. The sending or receiving station is connected to each of the headwall stations via pneumatic tubing. The at least one pump is adapted to create pressure differentiation within at least a subset of the pneumatic tubing. The at least one controller is adapted to selectively activate the at least one pump to route a medical object between the sending or receiving station and one of the headwall stations within the pneumatic tubing.

A coupling system for the media-conducting connection of two hose-like sections (10, 12) to form a common transport section (14), with each section having a coupling element (16, 18) having two coupling parts (20, 22) that can be separated from each other and that are detachably held together by closure elements (24) along a disconnecting point (26) which can be engaged with correspondingly formed closure elements (24) of the other coupling element (20, 22) to form the transport section (14), is characterized in that all closure elements (24) of the coupling parts (20, 22) point hose-inwards at least before the formation of the transport section (14) and in that at least when the transport section (14) is formed the respective disconnecting point (26) is arranged between the coupling elements (16, 18) transverse to this transport section (14).

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.

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 tube system, including at least one system control module for controlling delivery of a pneumatic carrier through pneumatic tubing. The system includes at least one pneumatic tube station having a sealer, the sealer includes a heating pad and a sealing strip, where the sealer automatically grips the open end within the heating pad and the sealing strip upon insertion of the bag into the system. In one example, the sealer creates a vacuum to extract air from an interior space of the bag. The sealer applies heat to the open end to seal the bag. The system includes at least one pneumatic tube station configured for sending at least one carrier, the at least one sending pneumatic tube station being in signal communication with the at least one system control module, where the at least one carrier is sent through the system by pneumatic tubing.

A pneumatic tube system, including at least one system control module for controlling delivery of a pneumatic carrier through pneumatic tubing. The system includes at least one pneumatic tube station having a sealer, the sealer includes a heating pad and a sealing strip, where the sealer automatically grips the open end within the heating pad and the sealing strip upon insertion of the bag into the system. In one example, the sealer creates a vacuum to extract air from an interior space of the bag. The sealer applies heat to the open end to seal the bag. The system includes at least one pneumatic tube station configured for sending at least one carrier, the at least one sending pneumatic tube station being in signal communication with the at least one system control module, where the at least one carrier is sent through the system by pneumatic tubing.