A workstation includes a housing and a pneumatic tube port sized and shaped to connect to tubing of a pneumatic tube delivery system. The workstation includes a carrier dispatch and arrival mechanism coupling to the pneumatic tube port and having an outlet and a slide plate movable from a position opening the outlet to a position closing the outlet. The carrier dispatch and arrival mechanism further including a dispatch arm for loading an outbound carrier for transportation from the workstation through the pneumatic tube delivery system to a further workstation. The workstation further comprises an equipment storage compartment adjacent to the carrier dispatch and arrival mechanism and a bin at the bottom of the housing sized and shaped to receive and store the inbound carriers in combination with a user interface cabinet housing a user interface apparatus and a space for supporting stored carriers.

A workstation includes a housing and a pneumatic tube port sized and shaped to connect to tubing of a pneumatic tube delivery system. The workstation includes a carrier dispatch and arrival mechanism coupling to the pneumatic tube port and having an outlet and a slide plate movable from a position opening the outlet to a position closing the outlet. The carrier dispatch and arrival mechanism further including a dispatch arm for loading an outbound carrier for transportation from the workstation through the pneumatic tube delivery system to a further workstation. The workstation further comprises an equipment storage compartment adjacent to the carrier dispatch and arrival mechanism and a bin at the bottom of the housing sized and shaped to receive and store the inbound carriers in combination with a user interface cabinet housing a user interface apparatus and a space for supporting stored carriers.

A workstation includes a housing and a pneumatic tube port sized and shaped to connect to tubing of a pneumatic tube delivery system. The workstation includes a carrier dispatch and arrival mechanism coupling to the pneumatic tube port and having an outlet and a slide plate movable from a position opening the outlet to a position closing the outlet. The carrier dispatch and arrival mechanism further including a dispatch arm for loading an outbound carrier for transportation from the workstation through the pneumatic tube delivery system to a further workstation. The workstation further comprises an equipment storage compartment adjacent to the carrier dispatch and arrival mechanism and a bin at the bottom of the housing sized and shaped to receive and store the inbound carriers in combination with a user interface cabinet housing a user interface apparatus and a space for supporting stored carriers.

In some examples, a landing device is configured to be disposed within a container receptacle of a pneumatic transport system, the landing device comprising: a landing platform defining a landing surface for a container of the pneumatic transport system, the landing platform comprising: a first material configured to at least partially deform in response to the container impacting the landing surface; and a second material disposed over the first material, the second material configured to facilitate removal of the container from the container receptacle; and a base mechanically connected to a second surface of the landing platform, the base configured to secure the landing device to the container receptacle, wherein the landing device is configured to be inserted into the container receptacle without removing one or more components of the container receptacle.

In some examples, a landing device is configured to be disposed within a container receptacle of a pneumatic transport system, the landing device comprising: a landing platform defining a landing surface for a container of the pneumatic transport system, the landing platform comprising: a first material configured to at least partially deform in response to the container impacting the landing surface; and a second material disposed over the first material, the second material configured to facilitate removal of the container from the container receptacle; and a base mechanically connected to a second surface of the landing platform, the base configured to secure the landing device to the container receptacle, wherein the landing device is configured to be inserted into the container receptacle without removing one or more components of the container receptacle.

A workstation includes a housing and a pneumatic tube port sized and shaped to connect to tubing of a pneumatic tube delivery system. The workstation includes a carrier dispatch and arrival mechanism coupling to the pneumatic tube port and having an outlet and a slide plate movable from a position opening the outlet to a position closing the outlet. The carrier dispatch and arrival mechanism further including a dispatch arm for loading an outbound carrier for transportation from the workstation through the pneumatic tube delivery system to a further workstation. The workstation further comprises an equipment storage compartment adjacent to the carrier dispatch and arrival mechanism and a bin at the bottom of the housing sized and shaped to receive and store the inbound carriers in combination with a user interface cabinet housing a user interface apparatus and a space for supporting stored carriers.

A workstation includes a housing and a pneumatic tube port sized and shaped to connect to tubing of a pneumatic tube delivery system. The workstation includes a carrier dispatch and arrival mechanism coupling to the pneumatic tube port and having an outlet and a slide plate movable from a position opening the outlet to a position closing the outlet. The carrier dispatch and arrival mechanism further including a dispatch arm for loading an outbound carrier for transportation from the workstation through the pneumatic tube delivery system to a further workstation. The workstation further comprises an equipment storage compartment adjacent to the carrier dispatch and arrival mechanism and a bin at the bottom of the housing sized and shaped to receive and store the inbound carriers in combination with a user interface cabinet housing a user interface apparatus and a space for supporting stored carriers.

A pneumatic post sleeve (10) has an insert (21) for receiving a test rod (20). In order that the test rod (20) always arrives in the same orientation and positionregardless of any rotation of the pneumatic post sleeve (10)the insert (21) is rotatable in the pneumatic post sleeve (10) about the longitudinal axis (17) of the sleeve tube (11), wherein the centre of gravity of the insert (21) together with the test rod (20) is located outside the longitudinal axis (17). As a result of its weight, the test rod (20) always takes up the lowest position. In order to improve precision, it is expedient for the insert (21) to be provided with a magnet (30) or with a magnetizable material close to the sleeve tube (11). The pneumatic post station (41) then has a horizontal reception tube (42), on the outside of which a permanent magnet or electromagnet (31) is provided, which is located opposite the magnet (30) in the case of a received pneumatic post sleeve (10). The two magnets try to get as close together as possible and as a result position the insert (21) even more precisely than would be possible by gravity alone. It is also possible for a plurality of magnet/magnetizable material and permanent magnet/electromagnet pairs to be provided.

A pneumatic post sleeve (10) has an insert (21) for receiving a test rod (20). In order that the test rod (20) always arrives in the same orientation and positionregardless of any rotation of the pneumatic post sleeve (10)the insert (21) is rotatable in the pneumatic post sleeve (10) about the longitudinal axis (17) of the sleeve tube (11), wherein the centre of gravity of the insert (21) together with the test rod (20) is located outside the longitudinal axis (17). As a result of its weight, the test rod (20) always takes up the lowest position. In order to improve precision, it is expedient for the insert (21) to be provided with a magnet (30) or with a magnetizable material close to the sleeve tube (11). The pneumatic post station (41) then has a horizontal reception tube (42), on the outside of which a permanent magnet or electromagnet (31) is provided, which is located opposite the magnet (30) in the case of a received pneumatic post sleeve (10). The two magnets try to get as close together as possible and as a result position the insert (21) even more precisely than would be possible by gravity alone. It is also possible for a plurality of magnet/magnetizable material and permanent magnet/electromagnet pairs to be provided.

A conveyor system (10) for transporting a transportable material (M) by means of a fluid for transporting the transportable material (M) between a first conveying line portion (11) and a second conveying line portion (12), said conveying line portions (11, 12) comprising a plurality of pipes forming a continuous conveying line (13), said system (10) comprising: a conveyor device (1) in fluid connection to one of said first or said conveying line portions (11, 12) operative to provide negative air pressure or vacuum through said conveying line (13); a material feeder device (2); wherein the conveyor device (1) comprises at least one material level sensor (1a, 1b), wherein the at least one material level sensor (1a, 1b) is used to monitor one or more material level(s) inside the conveyor device (1) and via one or more material level sensor lines (3) giving at least one material level signal (1aa, 1bb) to a controller (4) and from the controller (4) via a control signal line (5) transmit a control signal (5a) to the material feeder device (2) having a valve (6) adapted to control the amount of air injected into the system, typically the into the conveying line (13), wherein the controller (4) is adapted to control the valve (6) and/or a mass-flow (M), respectively, of the material feeder device (2) in dependence of output from the at least one material level sensor (1a, 1b) to control amount of air injected into the conveying line (13) at the feeder device (2).