An automatic analyzer is provided wherein degree of freedom in arrangement of a dispensing mechanism and of a unit provided below the dispensing mechanism is improved. The automatic analyzer comprising a dispensing mechanism driving a probe for a specimen or a reagent, wherein the automatic analyzer comprises an arm of two degrees of freedom supporting the probe, a first shaft and a second shaft that support the arm and transmit power to the arm, and a motor that gives power allowing the first and second shafts to be rotated and vertically moved, the second shaft being divided in an axial direction and having different diameters and, at the time of lowering the arm by the power of the motor, divided one of the second shaft being housed inside the other, whereby the second shaft is shortened.

A pipetting device, a system comprising the pipetting device, and a system for handling liquids and providing a pipetting device, the pipetting device comprising a housing with two parallel flat surfaces with a maximal distance of 17.5 mm between them accommodating a Z-shaft mounted in a guiding and connected to a Z-drive for actuating the Z-shaft; and a Y-drive which is connected to the housing and comprises a Y-gear wheel that is arranged next to an opening in the housing

A pipetting device includes pipetting unit(s), a guide assembly with at least one guide rail on which the pipetting unit(s) is guided in order to be moved along a movement axis, and a linear drive assembly, by which the pipetting unit(s) can be driven in order to be moved along the movement axis. The linear drive device has a stationary stator, and the at least one pipetting unit forms a linear drive assembly rotor which can be moved along the movement axis relative to the stator. The pipetting device also has at least two rotor magnet assemblies which interact with the same common stator magnet assembly so as to generate a drive force and which are arranged at a distance from one another along a spacing axis that is orthogonal to the movement axis. The common stator magnet assembly is located between the at least two rotor magnet assemblies.

A pipetting system having at least one pipette tip receptacle with a pipette tip arranged therein that extends along a vertical axis and at least one gripper having a mechanical coupling, the gripper is coupled to the at least one pipette tip receptacle with the coupling and at least one grip element. The at least one grip element has at least one substantially vertical portion and at least one substantially horizontal portion and the coupling has a body having a through channel that extends along the vertical axis over the entire length of the coupling and the pipette tip extends along the through channel of the coupling.

A pipetting device includes pipetting unit(s), a guide assembly with at least one guide rail on which the pipetting unit(s) is guided in order to be moved along a movement axis, and a linear drive assembly, by which the pipetting unit(s) can be driven in order to be moved along the movement axis. The linear drive device has a stationary stator, and the at least one pipetting unit forms a linear drive assembly rotor which can be moved along the movement axis relative to the stator. The pipetting device also has at least two rotor magnet assemblies which interact with the same common stator magnet assembly so as to generate a drive force and which are arranged at a distance from one another along a spacing axis that is orthogonal to the movement axis. The common stator magnet assembly is located between the at least two rotor magnet assemblies.

A pipetting apparatus (10) having a guidance frame (12) having a first linear guidance rail (52) and having a second linear guidance rail (56), the first and the second linear guidance rail (52, 56) proceeding parallel to one another along a displacement axis (VL) and being provided at a distance from one another orthogonally to the displacement axis (VL), and having a pipetting channel (14) which extends along a channel axis (K14) that is nonparallel, preferably orthogonal, to the displacement axis (VL) and which is guided displaceably along the displacement axis (VL) with a first bearing component (54) on the first linear guidance rail (52) and with a second bearing component (58) on the second linear guidance rail (56), is characterized in that the first and the second bearing component (54, 58) are arranged with a spacing (A) from one another along the displacement axis (VL).

A pipetting device includes pipetting unit(s), a guide assembly with at least one guide rail on which the pipetting unit(s) is guided in order to be moved along a movement axis, and a linear drive assembly, by which the pipetting unit(s) can be driven in order to be moved along the movement axis. The linear drive device has a stationary stator, and the at least one pipetting unit forms a linear drive assembly rotor which can be moved along the movement axis relative to the stator. The pipetting device also has at least two rotor magnet assemblies which interact with the same common stator magnet assembly so as to generate a drive force and which are arranged at a distance from one another along a spacing axis that is orthogonal to the movement axis. The common stator magnet assembly is located between the at least two rotor magnet assemblies.

A pipetting apparatus (10) having a guidance frame (12) having a first linear guidance rail (52) and having a second linear guidance rail (56), the first and the second linear guidance rail (52, 56) proceeding parallel to one another along a displacement axis (VL) and being provided at a distance from one another orthogonally to the displacement axis (VL), and having a pipetting channel (14) which extends along a channel axis (K14) that is nonparallel, preferably orthogonal, to the displacement axis (VL) and which is guided displaceably along the displacement axis (VL) with a first bearing component (54) on the first linear guidance rail (52) and with a second bearing component (58) on the second linear guidance rail (56), is characterized in that the first and the second bearing component (54, 58) are arranged with a spacing (A) from one another along the displacement axis (VL).

The invention relates to an adapter for mounting a conductive pipette, a sample tube opening/closing device, and an automatic sample analysis system and, more specifically, to an adapter for mounting a conductive pipette, a sample tube opening/closing device, and an automatic sample analysis system, in which dispensing of a liquid sample and extraction, amplification and testing of nucleic acids are integrally carried out. The sample tube opening/closing device includes: a housing that forms an inner space isolated from the outside and includes a door for carrying in/out a multi-well plate for biological samples, including a plurality of sample tubes in which biological samples are accommodated; and a sample tube opening/closing part that is installed in the inner space to be spaced apart from the multi-well plate for biological samples and automatically opens and closes the sample tubes.

A pipetting system having at least one pipette tip receptacle with a pipette tip arranged therein that extends along a vertical axis and at least one gripper having a mechanical coupling, the gripper is coupled to the at least one pipette tip receptacle with the coupling and at least one grip element. The at least one grip element has at least one substantially vertical portion and at least one substantially horizontal portion and the coupling has a body having a through channel that extends along the vertical axis over the entire length of the coupling and the pipette tip extends along the through channel of the coupling.