Provided herein are apparatuses and systems for mixing liquids and suspensions that include vessels with structures that improve mixing while not contacting liquid delivery components. The apparatuses and systems can include a motor drive that allows speed and directional control of rotation of the vessel. The apparatuses and systems can include one or more magnets for separating magnetic beads in a suspension. Also provided are methods using said apparatuses and systems for mixing and separation processes.

A mixing device includes a mixing container rotatable about a first axis of rotation for receiving mixing material, which has a mixer opening and a mixer cover which can be reciprocated between an opened position and a closed position. The mixer cover in the closed position closes the mixer opening and in the opened position exposes the mixer opening. The mixing container is rotatably mounted to a machine stand. The mixer cover is so fixed to the machine stand that the mixing container in the closed position of the mixer cover is rotatable relative to the mixer cover about the first axis of rotation. The machine stand has a stationary element and a pivotal element, wherein the pivotal element is mounted pivotably about a pivot axis relative to the stationary element. The mixing container is mounted rotatably to the pivotal element and the mixer cover is fixed to the pivotal element.

The present invention relates to a particle manipulation method to disperse magnetic particles 70 in a liquid 35 filling up a tube container 10, wherein a circumferential direction moving step to move the magnetic particles 70 along the circumferential direction of the container 10 in the liquid 35 and in a radial direction moving step to move the magnetic particles 70 as crossing the radial direction of the container 10 in the liquid 35 are implemented repeatedly. Such manipulations can be achieved by combining rotation of the container and gravity force and magnetic field manipulations.

The present invention provides a reagent mixing device, which comprises a driving device, a transport device and a rotating part, wherein the transport device comprises a conveying mechanism for conveying a reagent kit and a mixing mechanism for mixing a reagent; the conveying mechanism is driven by the driving device to move relative to the mixing mechanism; the rotating part and mixing mechanism are in transmission matching; the conveying mechanism and the mixing mechanism are sleeved with each other to form a bearing structure. The present invention further provides a reagent mixing method. The reagent mixing device is small in size, smart in structure, easy to assemble and low in manufacturing cost. The reagent mixing method provided by the present invention is simple and reliable, high in overall operation reliability, and has very high application values in such analysis and test fields as full-automatic chemiluminescence immunoassay analyzers and biochemical analyzers.

Provided is a liquid medication dispensing machine that can shorten the time to supply a liquid medication to a prescription bottle. The liquid medication dispensing machine is a liquid medication dispensing machine supplying a liquid medication from a liquid medication bottle containing the liquid medication to a prescription bottle, including a liquid medication stirring unit that stirs the liquid medication in the liquid medication bottle, a bottle holding unit that holds a plurality of liquid medication bottles including a first bottle containing a liquid medication G and a second bottle containing a liquid medication B, and a control unit that controls operation of the liquid medication dispensing machine. The control unit operates the liquid medication stirring unit to stir liquid medication B while liquid medication G is supplied from the first bottle to the prescription bottle.

Disclosed is a gripping device for a container intended for a biological analysis, including an annular part of X axis, elastically deformable gripping fins extending radially inwardly from the annular part, the fins being capable of being deformed when a container is introduced into the annular part, the fins being evenly distributed over the circumference. Each fin has a so-called upper surface and an opposite so-called lower surface, the lower surface being intended to come into contact with the container, the lower surface having a concave zone, or vice versa.

A wine decanter pedestal system includes a base supported above a surface, the base having a base center axis and a ledge extending outward from its top surface to support a bottom surface of a decanter placed on the top surface. A wireless receiver receives wireless commands from a wireless device to control a rotary motor operably coupled to the base at an attachment point off-center from the base center axis such that rotation of the rotary motor causes the base center axis to orbit about the rotary drive in a circular orbital motion and in a circular spin motion. A weight sensor measures a weight of a decanter placed upon the base, and a controller automatically adjusts the torque of the rotary drive in response to the weight measured by the weight sensor to increase torque for heavier weights measured and decrease torque for lighter weights measured.

A wine decanter pedestal system includes a base supported above a surface, the base having a base center axis and a ledge extending outward from its top surface to support a bottom surface of a decanter placed on the top surface. A wireless receiver receives wireless commands from a wireless device to control a rotary motor operably coupled to the base at an attachment point off-center from the base center axis such that rotation of the rotary motor causes the base center axis to orbit about the rotary drive in a circular orbital motion and in a circular spin motion. A weight sensor measures a weight of a decanter placed upon the base, and a controller automatically adjusts the torque of the rotary drive in response to the weight measured by the weight sensor to increase torque for heavier weights measured and decrease torque for lighter weights measured.

A device for cooling a slurry manufacturing mixer-comprises: a rotation container that comprises a mixing part, which mixes slurry and has a temperature detection part, and a slurry discharge part, which is formed under the mixing part and has a discharge hole for discharging the slurry; a body that is positioned under the rotation container and has a through-hole formed therethrough, through which the rotation container is inserted; and a sealing member interposed between the rotation container and the body, wherein the mixing part comprises an inner container and an outer container, and a cooling water passage is formed between the inner container and the outer container.

The present disclosure relates to the technical field of beverage mixers, in particular to a portable smart decanter, including a tray, a ball cover, balls, a rotary disc, a cam, a bearing, a motor, a motor cover, a diffusion ring, a USB charging port, a display, a key, a smart control drive, an upper cover, a lower cover, foot pads and a battery cover. The bottom center buckle of the lower cover is used to fix the battery cover. Through structure and function combination of various modules, when an object is placed on the tray of the on-off switch module, the force-bearing spring on the on-off switch module will touch the switch and make the internal circuit connected, and then the motor on the eccentric cam module begins to rotate and drive the ball sliding structure to slide.