An object of the present invention is to efficiently agitate and heat a liquid. To this end, the present invention provides an agitator supported on a rotating shaft, wherein such agitator has: a liquid suction port provided on the rotating shaft and/or near the rotating shaft; a liquid discharge port provided farther away than the liquid suction port from the rotating shaft, which is interconnected to the liquid suction port through an interconnecting channel; and a heater provided for heating the interior of the interconnecting channel and/or liquid discharge port.

Provided are a treatment method for a barren solution, and a treatment device for a barren solution, with which hydrogen sulfide can be efficiently removed from the barren solution. In an aeration tank provided with a vertical-type cylindrical reaction vessel, stirring blades arranged in the reaction vessel, and an annular aeration tube having a large number of air outlets, which is arranged to a bottom part of the reaction vessel, aeration is performed by blowing gas for aeration into the reaction vessel from a large number of air outlets of the aeration tube while stirring a liquid by rotation of the stirring blades.

Techniques or processes for efficiently producing concrete using dynamic feedback are disclosed. A concrete plant can use a control system to manage concrete production based on the dynamic feedback. The dynamic feedback can control mixing of concrete ingredients so as to yield uniform particle distribution for the concrete ingredients. The dynamic feedback can also avoid overflow situations as well as yield improved loading of the resulting concrete into a concrete transport vehicle (e.g., concrete truck).

An apparatus for mixing and cutting animal feed including a container with a sidewall, a rotary mixing and cutting device positioned inside the container and arranged to be driven by a driving unit. At least one counter element is provided at the sidewall. The apparatus includes a positioning device for moving the counter element between a retracted position and an inserted position, and a control unit to control the positioning device of the counter element and arranged to determine an indication of the amount of instantaneous power consumed by the driving units for driving the rotary mixing and cutting device and to control positioning device based on the determined indication of the amount of instantaneous power.

A manual mixer serves to facilitate mixing and agitating materials for use during surgery. For example, the manual mixer includes a body portion defining an interior area, a mixing assembly provided in the interior area of the body portion, a crank assembly for actuating the mixing assembly, and a valve assembly. The mixing assembly serves to mix and agitate the materials provided in the interior through rotation of a plunger portion and a spring attached thereto, and through upwards and downwards movement of the plunger portion in the interior area. Rotation of the crank assembly serves to rotate the plunger portion and the spring attached thereto, and effectuate upwards and downwards movement of the plunger portion. The valve assembly can be opened to facilitate dispensing of the materials from the interior area.

A mixing bag for use in bioprocessing in which a fluid is received and agitated using an internal fluid-agitating element driven by an external motive device is disclosed. The bag may include an integral sparger and sensor receiver. Related methods are also disclosed.

A lid (2) for closing a container (4) of liquid, the lid being provided with a spindle passageway (20) enabling an elongate body (30) of a stirrer member (3) for stirring the liquid to pass through the lid (2), which elongate body is designed to be mounted to rotate in the spindle passageway (20), the spindle passageway including a portion (23) for receiving the elongate body (30) and designed to allow the elongate body (30) of the stirrer member (3) to pass through it, and a portion (21) for receiving a seal (1), which portion has an inside diameter greater than the inside diameter of the portion (23) for receiving the elongate body (30) and receives an annular seal (1) designed to allow the elongate body of the stirrer member to pass through it. The inside peripheral face of the annular seal (1) is provided with a helical lip (120).

A blending apparatus includes a blending jar and a lid. The blending jar has an internal surface defining an internal volume, and a mixing blade positioned within the internal volume. The lid is releasably mounted to the blending jar and includes at least one scraper extending into the internal volume. The at least one scraper is adjacent to the internal surface of the blending jar and is arranged and configured to disrupt rotational flow of food particles within the internal volume and/or scrape food particles from an inner surface of the blending jar.

The enclosed offset pail mixer is an invention which allows for safe, efficient and clean mixing of liquid solutions and liquid mechanical mixtures. The mixer includes a moveable head assembly that is constrained to two positions. In the operating position, the mixer geometry substantially encloses the moving parts of the mixer, preventing personnel from coming in contact with moving parts. The geometry also acts to contain dusts and vapors. A safety control circuit ensures that the impeller motor will not operate unless the vessel and the shroud are both in their respective operating position. In the operating position, the impeller shaft axis is strategically offset from the vessel axis to reduce large vortices and associated aeration. When the movable head is in the retracted position, the impeller is positioned over a removable drip cup to prevent residue from dripping on the floor or machine frame.

A mixing apparatus has a mixing container disposed in the upper part of the mixing apparatus, preferably standing on a frame, which is open towards the top. The mixing container includes a single-shaft agitator disposed in the lower part of the mixing apparatus. The agitator has a vertically disposed agitator shaft to which is fastened an agitating tool configured as a rotor body which is disposed in the mixing container just above the container base. The single-shaft agitator is a statorless agitator and the rotor body fastened to the agitator shaft is surrounded by an external free space between the rotor body and the container wall of the mixing container. The agitator shaft is adjustable in its spacing distance from the cylinder axis.