A conveyor assembly for transporting a carrier coupled to a receptacle to a processing station located within a housing of an instrument. The conveyor assembly includes a spur conveyor subassembly and a buffer conveyor subassembly for transporting the carrier from a host conveyor assembly to the spur conveyor subassembly. The spur conveyor subassembly includes (i) a rotatable diverter having at least one recess for receiving and moving the carrier between the buffer conveyor subassembly and the spur conveyor subassembly and (ii) a gripper configured to grasp the carrier and move it from the diverter to the processing position located within the housing of the instrument.

A conveyor assembly for transporting a carrier coupled to a receptacle to a processing station located within a housing of an instrument. The conveyor assembly includes a spur conveyor subassembly and a buffer conveyor subassembly for transporting the carrier from a host conveyor assembly to the spur conveyor subassembly. The spur conveyor subassembly includes (i) a rotatable diverter having at least one recess for receiving and moving the carrier between the buffer conveyor subassembly and the spur conveyor subassembly and (ii) a gripper configured to grasp the carrier and move it from the diverter to the processing position located within the housing of the instrument.

An automated conveyor assembly for transporting a carrier coupled to processing receptacle from (i) a carrier conveyor assembly to (ii) a processing position within an instrument, where the automated conveyor assembly includes a gripper configured to selectively grasp a carrier and move between (i) a first position and (ii) the processing position in the instrument. The automated conveyor assembly further includes a diverter defining a recess configured to receive a carrier, the diverter being rotatable between (i) a first position at which the recess is aligned with the carrier conveyor assembly and (ii) a second position at which the recess is aligned with the first position of the gripper.

Systems and methods for use in an in vitro diagnostics setting incorporating magnetic shielding to reduce exposure of any of samples, reactants, devices or people from exposure or prolonged exposure to magnetic or electromagnetic fields generated with the system. Some embodiments provide an automation system for use in an in vitro diagnostics setting comprising an automation track having a sidewall provided with magnetic shielding. In some embodiments, the magnetic shielding comprises an 80% nickel alloy.

A sample transport method, applied to a test instrument including a conveyor belt, and a loading platform and a grab position sequentially disposed along a transport direction of the conveyor belt, wherein a plurality of sample holder transport positions are disposed on the conveyor belt; the method including: pushing a first sample holder from the loading platform to a sample holder transport position of the conveyor; when a sample position on the first sample holder moves to the grab position, determining whether the sample position moved the grab position is a target sample position; if so, then determining whether all samples positions on the first sample holder before the target sample holder other than a predetermined number of sample positions have completed testing, wherein the predetermined number is sample position number corresponding to a delay time in outputting information indicating whether a sample needs to be retested.

A laboratory sample distribution system comprising a plurality of sample container carriers, each adapted to carry one or more sample containers, each carrier comprising at least one magnetically active device and at least one electrically conductive member, a transport plane adapted to support the carriers, a plurality of electro-magnetic actuators stationary arranged below the transport plane, the actuators being adapted to move the carriers on top of the transport plane by applying a magnetic force to the carriers, a plurality of inductive sensors distributed over the transport plane, a control unit configured to control the movement of the carriers using an output signal provided by the inductive sensors by driving the actuators such that the carriers move along corresponding transport paths, and an evaluation unit configured to linearize the output signal from an inductive sensor by means of a linearization algorithm.

A container supply unit is provided with a container retaining unit, a container discharge unit, and a container alignment unit. The container alignment unit is provided with an alignment rail. The alignment rail includes a conveying speed ensuring area and an orientation stabilizing area. The conveying speed ensuring area is inclined with respect to a horizontal direction. The orientation stabilizing area is provided continuously on a downstream side in a conveying direction of the conveying speed ensuring area in which an inclination angle with respect to the horizontal direction is set to be smaller than that in the conveying speed ensuring area. Then, the transfer position is provided on a downstream side in the conveying direction of the orientation stabilizing area, and is arranged so as to be parallel to the horizontal direction.

The present disclosure relates to a sample rack loading system and loading method, and a chemiluminescence detector. The loading system includes: a sample rack storage device, provided with multiple sample holders for storing sample racks; a sample rack transmission device, comprising a rail component and a sample rack block piece mechanism; and a sample rack transfer device, transfers the sample racks between the sample rack storage device and the sample rack transmission device; the sample rack block piece mechanism is configured to block or unblock transmission passages of the rail component; and a guide block is arranged on the sample rack transfer device. When transfer rails of the sample rack transfer device are in abutment with the transmission passages, the guide block drives the sample rack block piece mechanism to unblock the transmission passages.

A test piece storage container continuous processing apparatus capable of continuously introducing a test piece storage container into a housing and suitably coping with numerous samples. The continuous processing apparatus X is applied to a measuring apparatus Y which removes a test piece P from a test piece storage container B equipped with an opening and closing lid B2 and performs predetermined measurement processing, and further includes an introduction transfer unit 1 for transferring the test piece storage container B introduced from the introduction starting end 11 set outside the housing Y1 of the measuring apparatus Y to a predetermined test piece take-out position in the housing Y1, a lid opening unit 2 for switching the opening and closing lid B2 from a closed state to an open state at the test piece take-out position, and a discharge unit 31 for discharging the test piece storage container B from which the test pieces P have been removed to a discharge port 31, wherein the introduction starting end is set to be accessible from the outside of the housing Y1, and the test piece storage container B is configured to be transferable in one direction from the introduction starting end 11 to the discharge port 31.

A transporting device for transporting a laboratory diagnostic vessel carrier from a first line portion to a second line portion of a conveying line is disclosed. The first line portion is above the second line portion with respect to gravity. The transporting device comprises first and second transporting portions. The first transporting portion is connected to the first line portion and the second transporting portion is connected to the second line portion. The first transporting portion extends in a first direction and the second transporting portion extends in a second direction different from the first direction. The first and second transporting portions transport the laboratory diagnostic vessel carrier by gravity. The first direction comprises at least a first component and the second direction comprises at least a second component. The second component is opposite to the first component. Further, a conveying line comprising such a transporting device is disclosed.