A modular centrifuge device for separating fluid samples, including a housing having a modular power assembly mechanism for rotating samples with manual or electric power. A manual centrifuge device, including a housing having a power assembly mechanism for rotating samples with manual power, and a speed indicator for indicating if a predetermined speed has been reached and a time indicator for indicating if a predetermined or calculated time has been reached for rotating said samples operatively connected to the device. A method of centrifuging samples, by selecting a manual power mode or electric power mode on a centrifuge, rotating samples at a predetermined speed for a predetermined or calculated time, alerting a user that the predetermined speed and predetermined or calculated time have been achieved, and obtaining separated samples.

A rotor assembly includes a rotor plate to rotate around a first axis, a bucket attached to the rotor plate and to rotate around a second axis, and a stop plate to rotate around the first axis between an open position and a closed position. When in the closed position, the stop plate engages the bucket to fix an angular position of the bucket relative to a plane of rotation of the rotor assembly. The rotor assembly further includes a housing for a sensor array component, the housing disposed in the bucket and including a solution inlet, a solution outlet, a transfer basin, a solution retainer disposed between the solution outlet and the transfer basin, and a collection reservoir in fluid communication with the transfer basin. The solution inlet and the solution outlet to engage ports of a flow cell of a sensor array.

A centrifuge insert is provided which is not only suited for one type of sample container or sample carrier but for at least two geometrically different elements from the group consisting of sample container and sample carrier. This achieves that the same centrifuge insert can be used for different sample containers or sample carriers. This provides space savings, in particular in the lab. Furthermore acquisition cost is reduced, and handling is accelerated by reducing manual complexity which increases lab through put.

A swinging bucket centrifuge (1) comprises a rotor (10) with at least one mounting end and at least one bucket (20) mounted to the at least one mounting end of the rotor (10). Therein, the at least one bucket (20) is mounted to the at least one mounting end of the rotor (10) by at least one clevis pin (30) held in a clevis (13) so that the bucket (20) is pivotable about the clevis pin (30).

A centrifuge comprising a rotor having a rotational axis, at least one receptacle for a blood sample container, controller means for controlling the rotational speed of the rotor, at least one optical transmitter for transmitting an optical signal, at least one optical receiver for registering the amplitude of the optical signal, where the optical signal is configured to pass through the blood sample container where the optical receiver detects the amplitude of the optical signal when it is directed through the blood sample container, where the amplitude of the optical signal reflects the translucency of the blood sample, where the controller means is configured to discontinue the rotational movement of the rotor when the amplitude of the optical signal over time has fulfilled a predefined pattern indicating that at least the fibrin compression phase of the blood sample is started.

Provided is a swing rotor for a centrifuge. The centrifuge includes a swing type rotor body having a plurality of holding pins and a plurality of buckets held by the holding pins in a swingable manner. On the rotor body, a connection part is formed to connect two branch arms that diverge from an arm part on an outer peripheral side. A thickness-reduced part penetrating in the same direction as a driving shaft is formed in a region surrounded by the two branch arms on an inner peripheral side of the connection part. Since the branch arms deform accordingly to a certain extent, partial concentration of the stress applied on the holding pins due to a centrifugal load can be alleviated. Thus, the lifespan of the centrifuge can be improved and the centrifugal separation operation can be stabilized.

The invention relates to an arrangement (10) for preparing a plurality of samples for an analytical method, comprising a carousel (14) with a solid housing (12) and moveable receiving parts (16) for the sample containers (18); a control for controlling the receiving parts (16) in the carousel (14); and a sample receiving device (24) for providing the sample to be analysed; one or more stations (24, 26, 28, 30, 32) for preparing samples are provided on the carousel (14), the receiving parts (16) for the sample containers (18) of the carousel (14) can be positioned on said stations; a centrifuge (22) with pairs of opposite lying receiving parts (42) provided for the sample containers (18), and said receiving parts (42) are arranged such that they can move on the centrifuge (22) and the movements can be controlled in such a manner that the sample holder (18) can be transferred between a receiving part (16) in the carousel (14) and a receiving part (42) in the centrifuge (22).

A centrifuge includes a swing rotor. Rotor arms of the swing rotor have recesses into which hangers of the swing rotor at least partially swing in a swung-out state. As a result, the centrifuge container and thus also the centrifuges are more compact, because the swinging-out requires less space. An inertial mass of the swing rotor is reduced due to the recesses provided therein, whereby energy consumption, primarily when starting the centrifuge, is significantly reduced.

A centrifuge and a rotor thereof are provided. The centrifuge performs centrifugation in a state where the sample container is swung by rotation and seated in a cutout part of a rotor body. The sample container includes a bucket accommodating a container filled with a sample, and a lid for sealing the bucket and having a rotation shaft. Grooves extending in the longitudinal direction are formed on the outer peripheral surface of the bucket on the bottom side with respect to a seating surface of the bucket. The grooves are arranged at equal intervals in the circumferential direction. Formation of the grooves can prevent increasing the weight of the bucket and realize a highly rigid sample container that can withstand deformation.

A centrifugal processing unit for directing the movement of substances within a sample processing cartridge has a rotor with an accommodation for receiving the sample processing cartridge, the accommodation only allowing a free pivoting motion of the cartridge about a respective pivot axis, wherein each pivot axis is orthogonal to the rotor axis and to a respective force vector of a centrifugal force, a rotor drive to create the centrifugal force, a blocking element, allowing the free pivoting motion of the cartridge in a release position and preventing the free pivoting motion in a blocking position, wherein the blocking element is arranged on the rotor spaced apart above the accommodation is disclosed.