This application provides a method for controlling a planar drive system, where the planar drive system comprises at least a controller, a stator module having a stator surface, and a rotor that may is positionable and movable on the stator surface. The method comprises positioning an object on a rotor in a first arrangement state of the object in a positioning step, carrying out an accelerating movement of a defined movement pattern of the rotor; and, by the accelerating movement, arranging the object positioned on the rotor in the first arrangement state in a second arrangement state relative to the rotor, in an arranging step. The application further provides a planar drive system.

A split shaker for an incubator, the incubator defining an incubation chamber, wherein the split shaker includes a disk drive motor for driving a shaking table, a disk drive motor including a stator assembly disposed outside the incubation chamber, and a rotor assembly disposed inside the incubation chamber having a central shaft and a rotor turntable mounted on the central shaft; wherein the rotation of the rotor turntable drives a shaking movement of the shaking table.

The present disclosure provides a device for assisting agitation of liquid. The device includes a frame having a bottom and a sidewall forming an angle with the bottom; a first flexible film attached to the frame at a periphery portion of the first flexible film; a first magnetic field generator at the sidewall of the frame and adjacent to the periphery portion of the first flexible film; and a second magnetic field generator at the bottom of the frame, wherein the first magnetic field generator and the second magnetic field generator are configured to provide a magnetic field parallel to at least a portion of the first flexible film, and wherein a portion of the frame and the first flexible film are configured to be in contact with the solution.

Analysis devices for observing and measuring sample solutions have had a problem in which an irregular sample distribution will lead to irregular measurement results and measurement error. That is why it is preferable for a sample solution to have an average sample distribution. To address the abovementioned problem, this analysis device is made to comprise a sample container holding part and a conveying stage and is characterized by comprising a vibration mechanism for using electrical current and a magnet to vibrate the sample container holding part above a conveying path and mixing a sample solution in a container.

A microtiter plate mixing control system is disclosed. The system includes a frame, a suspension system attached to the frame, and a magnetically responsive horizontal platform supported on the frame by the suspension system. A solenoid is adjacent the platform for moving the platform on the suspension system. A proximity sensor is adjacent the platform for determining the position of the platform with respect to the frame. A controller is in communication with the proximity sensor and the solenoid for driving the solenoid and moving the platform in response to the proximity sensor.

A device for mixing liquids and solids in liquids using vibration includes an electromagnetic drive, a drive shaft arranged coaxially with the electromagnetic drive, with drive shaft having a mixing member and either a permanent magnet or a magnetisable element excited by the electromagnetic drive to cause vibration for transmission to the mixing member, and a system of flat spring elements including a first spring element arranged parallel to the drive shaft and a second spring element arranged perpendicularly to the drive shaft and connected to the permanent magnet or the magnetisable element.

A mixing apparatus includes a well plate assembly including a fixed support, and a well movable with respect to the fixed support. A fixed sensor mount has a first portion disposed above the well and a second portion disposed within the well. A plurality of electromagnets are operable to move the well plate assembly vertically with respect to the fixed sensor mount and the fixed support.

Disclosed is a process photometer arrangement (10) with a photometric cuvette unit (20) comprising a cuvette body (24) defining a cuvette cavity (25) and a combined sample inlet/outlet opening (34), a photometer light inlet window (60) and a photometer light outlet window (62). The cuvette body (24) is movably supported by a cuvette body support element (88) and the cuvette unit (20) is provided with a cuvette vibration device (80) for vibrating the cuvette body (24) to thereby quickly and homogenously mix a liquid sample volume (31) within the cuvette cavity (25) without any separate mixing element within the cuvette cavity. This allows a short mixing action within a microfluidic cuvette.

A microtiter plate mixing control system is disclosed. The system includes a frame, a suspension attached to the frame, and a magnetically responsive horizontal platform supported on the frame by the suspension. A solenoid is adjacent the platform for moving the platform on the suspension. A proximity sensor is adjacent the platform for determining the position of the platform with respect to the frame. A controller is in communication with the proximity sensor and the solenoid for driving the solenoid and moving the platform in response to the proximity sensor.

A blending appliance in accordance with the principals of the present invention includes a linear motor drive comprising a magnet structure secured to a reaction mass and a coil structure secured to a shaker platen, the shaker platen adapted to secure a blending cup. A third mass is secured to the reaction mass via at least one biasing member. A ground is secured to the third mass via at least one biasing member. The shaker platen is secured to the reaction mass via at least one biasing member. The magnet structure and coil structure impart a force to the reaction mass and the shaker platen, which force is driven by the biasing members and the masses of the shaker platen, the reaction mass, and the third mass into resonance, thereby maximizing payload amplitude, minimizing forces transmitted to ground, and minimizing driver amplitude. The smoothie blending cup comprising structure to generate at least two forces applied upon the smoothie ingredients, the forces selected from the group consisting of pulverizing force, shear force, rotational-kinetic energy force, radial-kinetic energy force, and combinations thereof. The smoothie blending cup and cap can be sealed with the beverage ingredients contained therein at the point of manufacture.