Provided is an ultra-dispersion mixer, for stirring a mixed material for producing a high-quality slurry for an electrode of a secondary battery within a short time by disposing a low-speed blade and a high-speed blade for stirring a mixed material in a chamber so as to easily and effectively disperse elements of the slurry of a secondary battery, supplied to a mixer during a procedure of preparing the slurry of a secondary battery produced by performing mixing procedures multiple times, and disposing blade parts having a plurality of stirring characteristics so as to realize various stirring characteristics in the mixed material on the high-speed blade to increase the dispersion of the mixed material while the mixed material circulates in a high-shear disperser of the chamber and to simultaneously increase the temperature of a supplied solution at the beginning of stirring of the mixed material in the chamber.

A bioreactor system includes a support housing having an interior surface bounding a compartment, the support housing having a sidewall with an opening extending therethrough and communicating with the compartment. A rack is secured to the support housing in alignment with the opening. An elongated first shaft has a first end and an opposing second end, the first end of the first shaft being secured to the rack so that the second end of the first shaft projects outwardly away from the sidewall of the support housing. A structure is secured to the first shaft towards the second end of the first shaft, the structure outwardly projecting away from the first shaft. A collapsible bag bounds a chamber and is at least partially disposed within the compartment of the support housing. A member projects from the collapsible bag and passes through the opening on the sidewall, the structure restraining movement of the member.

Systems and methods for providing and using a bone cement mixer are described. While the systems can include any suitable component, in some cases, they include a container that is configured to hold an amount of bone cement, a drive shaft coupled to the container, a mixing arm that is coupled to the container and configured to mix the bone cement when the bone cement is disposed within the container, and a vacuum pump configured to draw gas from within the container to form at least a partial vacuum within the container. In some cases, the drive shaft is mechanically coupled to the mixing arm and the vacuum pump such that rotation of the drive shaft forces the mixing arm to move and the vacuum pump to be actuated. Other implementations are also described.

The present invention concerns a casting sand cooler comprising a sand chamber having an air inlet optionally with a fan for the feed of air into the sand chamber and an air outlet optionally with a fan for sucking air out of the sand chamber. To provide an improved casting sand cooler in which the sand discharge during the cooling operation by way of the air outlet is markedly reduced, it is proposed according to the invention that a dynamic wind sifter which is rotatable about an axis and which is so arranged that substantially the complete air flow leaving the sand chamber through the air outlet is passed through the dynamic wind sifter.

A pump that includes a rotatable shaft, a material driving apparatus mounted to the rotatable shaft, as well as a conduit in which the rotatable shaft as well as the material driving apparatus are contained, wherein the pump is capable of reliably pumping viscous material through and out of the conduit.

A system for blending cement and at least one additive during a blending job to create a cement slurry for use in an underground hydrocarbon well includes a mixing tub, at least first and second blenders and a rotatable platform upon which the blenders are mounted. Each blender includes at least one elongated, rotatable, mixing blade extending into the tub to mix the cement and at the additive(s) to form the cement slurry.

A bioreactor system includes a support housing having an interior surface bounding a compartment, the support housing having a sidewall with an opening extending therethrough and communicating with the compartment. A rack is secured to the support housing in alignment with the opening. An elongated first shaft has a first end and an opposing second end, the first end of the first shaft being secured to the rack so that the second end of the first shaft projects outwardly away from the sidewall of the support housing. A structure is secured to the first shaft towards the second end of the first shaft, the structure outwardly projecting away from the first shaft. A collapsible bag bounds a chamber and is at least partially disposed within the compartment of the support housing. A member projects from the collapsible bag and passes through the opening on the sidewall, the structure restraining movement of the member.

Provided is a mixing device that is configured to install therein a multi-well plate including a plurality of wells capable of containing matter to be mixed and includes mixing mechanisms each of which mixes the matter to be mixed with a motor and is provided for each of the wells. The mixing mechanisms each includes a first rotator that is connected to the motor and rotates due to activation of the motor, a mixing rod that mixes the matter to be mixed, a second rotator that supports the mixing rod, a magnetic coupling mechanism that magnetically couples the first rotator to the second rotator, and a seal ring that surrounds an opening of the well and is capable of closing the well together with the second rotator.

A batch or continuous mixer for mixing powders, immiscible liquids, or a powder with a liquid includes one or more vibrational energy applicators which propagate vibrational energy into the mixture, causing powders to flow like liquids and breaking up liquid droplets and powder clumps. In embodiments, the vibration frequency and amplitude are selected according to properties of the mixture components. Vibrations can be propagated through container walls, impellers, or other structures within the mixing container. Vibrated structures can be flexibly supported for enhanced propagation of the vibrations. Vibrational energy can be uniform throughout the container, or focused in a desired region. Ultrasonic energy can be simultaneously applied with acoustic energy.

A fluid mixing system includes a support housing having an interior surface bounding a compartment, the support housing having a floor and a sidewall upstanding therefrom, an opening extending through the sidewall and communicating with the compartment. An elongated rack is disposed on the support housing adjacent to the opening. A first hanger includes an elongated shaft having a first end and an opposing second end, the first end of the shaft being removably mounted to the rack so that the second end projects outwardly away from the sidewall of the support housing, the second end of the shaft having a fastener disposed thereat.