A magnetic mixing apparatus is disclosed. A magnetic mixing apparatus according to one embodiment of the present invention comprises: a shaft which passes through a driving motor unit and which is rotatably coupled to the driving motor unit; a first housing which is coupled to one side of the driving motor unit and which is provided outside a stirring container to accommodate an upper part of the shaft; a rotary rotor which is coupled to the end of the shaft at a stirring container side during normal operation and which has a first permanent magnet; and an impeller unit which is arranged inside the stirring container and which has a second permanent magnet magnetically coupled to the first permanent magnet during normal operation, wherein the first housing includes a magnetic separation rotary rotor support part formed to protrude inward so as to support, from the downward direction, the rotary rotor, which is down-driven so as to move downward from the shaft, when there is magnetic separation by which magnetic coupling is released through magnetic deformation of the first permanent magnet and/or the second permanent magnet.

The present invention relates to a bioreactor agitator. According to one embodiment of the present invention a drive coupling part is coupled to an impeller part through the drive coupling part, and the rotary shaft coupled to the impeller by means of magnetic force is provided to be adjustable in height by means of an up-and-down transfer part, such that the entire interior of the housing part can be effectively stirred.

The present invention relates to a bioreactor agitator. According to one embodiment of the present invention a drive coupling part is coupled to an impeller part through the drive coupling part, and the rotary shaft coupled to the impeller by means of magnetic force is provided to be adjustable in height by means of an up-and-down transfer part, such that the entire interior of the housing part can be effectively stirred.

An impeller, for example, a Rushton impeller for a bioreactor system is disclosed. The impeller includes a hub, optionaly including a slot, a plurality of blades, and one or more turbulators. The plurality of blades is disposed along a circumferential direction of the hub and spaced apart from each other. Each of the plurality of blades is coupled to at least a portion of a circumference and/or a top surface of the hub. Each blade of the plurality of blades includes a pressure face and a suction face. The one or more turbulators is disposed on at least a portion of the suction face, the pressure face, or both, of a blade of the plurality of blades.

Magnetic-based actuation mechanisms for and methods of actuating magnetically-responsive microposts in a reaction (or assay) chamber is disclosed. For example, a microfluidics system is provided that includes a microfluidics device (or cartridge) that includes the reaction (or assay) chamber in which a field of magnetically-responsive surface-attached microposts is installed. The presently disclosed magnetic-based actuation mechanisms are provided in close proximity to the magnetically-responsive microposts wherein the magnetic-based actuation mechanisms are used for actuating the magnetically-responsive microposts. For example, the magnetic-based actuation mechanisms generate an actuation force that is used to induce, for example, synchronized beat patterns and/or metachronal beat patterns in the magnetically-responsive microposts. Additionally, a method of using the presently disclosed magnetic-based actuation mechanisms for actuating the magnetically-responsive microposts is provided.

Magnetic-based actuation mechanisms for and methods of actuating magnetically-responsive microposts in a reaction (or assay) chamber is disclosed. For example, a microfluidics system is provided that includes a microfluidics device (or cartridge) that includes the reaction (or assay) chamber in which a field of magnetically-responsive surface-attached microposts is installed. The presently disclosed magnetic-based actuation mechanisms are provided in close proximity to the magnetically-responsive microposts wherein the magnetic-based actuation mechanisms are used for actuating the magnetically-responsive microposts. For example, the magnetic-based actuation mechanisms generate an actuation force that is used to induce, for example, synchronized beat patterns and/or metachronal beat patterns in the magnetically-responsive microposts. Additionally, a method of using the presently disclosed magnetic-based actuation mechanisms for actuating the magnetically-responsive microposts is provided.

An aspect of the invention discloses a system for making lather in a cup, comprising a cup comprising an impeller and a heater in said cup and a base for said cup having a power source configured to provide power to said impeller and to said heater.

An aspect of the invention discloses a system for making lather in a cup, comprising a cup comprising an impeller and a heater in said cup and a base for said cup having a power source configured to provide power to said impeller and to said heater.

A carbonated beverage maker includes a water reservoir, a carbon dioxide creation chamber, and a carbonation chamber. The water reservoir holds ice water and has a first impeller and a shroud surrounding the first impeller. The carbon dioxide creation chamber contains chemical elements and receives warm water. The chemical elements react with each other to create carbon dioxide when the warm water is introduced to the carbon dioxide creation chamber. The carbonation chamber is connected to the water reservoir and the carbon dioxide creation chamber. The carbonation chamber has a second impeller that includes a stem portion and blades. The stem portion and the blades define conduits therein. The blades create a low pressure region in a lower portion of the carbonation chamber such that carbon dioxide from the carbon dioxide creation chamber flows through the conduits to the low pressure region.

The present invention provides a cartridge, a detection method, and a detection device capable of stabilizing the liquid level of a sample accommodated in a chamber in a predetermined state. A cartridge 20, that is rotated around a rotating shaft 42 for detecting a target substance, is provided with a chamber 100 in which a sample containing a target substance is stored. The chamber 100 includes a first region 110 in which a sample is stored, a second region 120 disposed at a position closer to the rotating shaft 42 than the first region 110, and a protrusion 130 protruding from a position between the first region 110 and the second region 120 to the inner side of the chamber 100.