A centrifugal air-oil separator system for a gas turbine engine system is described. The air-oil separator system has a rotatable shaft and the shaft includes an axially extending bore formed at least partially through the shaft. A gear is integral to or mounted on an outer surface of the shaft. The air-oil separator system also includes a bolt-on breather mounted on the shaft and independent from and in contiguous contact with the gear to assist in separating the oil from the air. Various types of materials may be utilized in the construction of the air-oil separator system.

A centrifugal air-oil separator system for a gas turbine engine system is described. The air-oil separator system has a rotatable shaft and the shaft includes an axially extending bore formed at least partially through the shaft. A gear is integral to or mounted on an outer surface of the shaft. The air-oil separator system also includes a bolt-on breather mounted on the shaft and independent from and in contiguous contact with the gear to assist in separating the oil from the air. Various types of materials may be utilized in the construction of the air-oil separator system.

A portable centrifuge having a housing containing a rotational mechanism and a centrifugal container having a longitudinal axis. The rotational mechanism has a circuit including an electrical motor, a switch, and an internal electrical power source. The centrifugal container is operably connected to the rotational mechanism through the housing, and is rotatable about the longitudinal axis. The centrifuge is portable and is for single use.

A portable centrifuge having a housing containing a rotational mechanism and a centrifugal container having a longitudinal axis. The rotational mechanism has a circuit including an electrical motor, a switch, and an internal electrical power source. The centrifugal container is operably connected to the rotational mechanism through the housing, and is rotatable about the longitudinal axis. The centrifuge is portable and is for single use.

The invention relates to a flow-through centrifuge which is used, for example, for biotechnical applications, in particular as a blood centrifuge. A driving arrangement and/or transmission arrangement of the flow-through centrifuge comprises a planetary gearset. In the planetary gearset, at least one planetary belt pulley is rotatably supported on a rotating planet carrier. A torque of the planetary belt pulley is transmitted via a belt. The planet carrier and the planetary belt pulley are driven at different rotational speeds. According to the invention, the planet carrier is held by a belt tensioning unit rotating with the planet carrier. A distance of the planet carrier from a rotor axis can be changed via the belt tensioning unit in order to adjust the belt tension of the belt.

The invention relates to a flow-through centrifuge which is used, for example, for biotechnical applications, in particular as a blood centrifuge. A driving arrangement and/or transmission arrangement of the flow-through centrifuge comprises a planetary gearset. In the planetary gearset, at least one planetary belt pulley is rotatably supported on a rotating planet carrier. A torque of the planetary belt pulley is transmitted via a belt. The planet carrier and the planetary belt pulley are driven at different rotational speeds. According to the invention, the planet carrier is held by a belt tensioning unit rotating with the planet carrier. A distance of the planet carrier from a rotor axis can be changed via the belt tensioning unit in order to adjust the belt tension of the belt.

A centrifuge including a rotor having at least one recess, at least one protrusion or a combination of the at least one recess or the at least one protrusion defining a concave arrangement, each of the at least one recess, the at least one protrusion or the combination of the at least one recess or the at least one protrusion adapted to receive a corresponding specimen container.

A centrifuge including a rotor having at least one recess, at least one protrusion or a combination of the at least one recess or the at least one protrusion defining a concave arrangement, each of the at least one recess, the at least one protrusion or the combination of the at least one recess or the at least one protrusion adapted to receive a corresponding specimen container.

A drive head (20) of a centrifuge drive for detachably connecting a rotor to the centrifuge. The drive head includes a drive head hub (74) having a plurality of recesses (98) spaced circumferentially and symmetrically about the drive head hub, a locking shoe (80) movably retained within each of the plurality of recesses and movable radially therein, and a resilient element (102) located between each locking shoe and the drive head hub for biasing each locking shoe in a radially outward direction relative to the rotational axis of the centrifuge drive. Each locking shoe is configured to exert a radially outwardly directed force on an interior sidewall of the hub of the centrifuge rotor to prevent axial movement of the centrifuge rotor along the rotational axis of the centrifuge drive and rotational movement of the centrifuge rotor relative to the drive head, with the radially outwardly directed force increasing with a rising rotational speed of the drive head.

A drive head (20) of a centrifuge drive for detachably connecting a rotor to the centrifuge. The drive head includes a drive head hub (74) having a plurality of recesses (98) spaced circumferentially and symmetrically about the drive head hub, a locking shoe (80) movably retained within each of the plurality of recesses and movable radially therein, and a resilient element (102) located between each locking shoe and the drive head hub for biasing each locking shoe in a radially outward direction relative to the rotational axis of the centrifuge drive. Each locking shoe is configured to exert a radially outwardly directed force on an interior sidewall of the hub of the centrifuge rotor to prevent axial movement of the centrifuge rotor along the rotational axis of the centrifuge drive and rotational movement of the centrifuge rotor relative to the drive head, with the radially outwardly directed force increasing with a rising rotational speed of the drive head.