Aspects of this disclosure relate to a vessel support apparatus and to uses of the vessel support, such as in the laboratory setting. Apparatus of this disclosure may secure a vessel thereto, such as when the apparatus is in operation or use. Vessel support apparatus will comprise a vessel supporting means and one or more means for securing the vessel to the supporting means.

A blending machine, for homogenizing materials deposited within an intermediate bulk container (IBC), includes: a frame; a drive motor; a clamp disk rotatably supported by the frame and coupled to the drive motor to drive disk rotation; first and second jaw clamps movably mounted to the frame; and a drive mechanism to drive the jaw clamps to translate toward each other and rotatably secure the IBC's boom to the rotatable clamp disk. A clutch, a torque limiter, and a limit switch limit the pressure applied by the clamps, and the extent of their travel to optimize clamping and rotatability. The blending machine is moveably mounted to a pedestal, and elevated by an actuator. A blending bar within the IBC is coupled through the boom to the clamp disk, and driven to rotate to blend the materials, in addition to mixing by rotation of the ICB.

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 direct-drive dental material mixing device includes a motor, a seat and a clamp, the motor includes a stator and a rotor including an output shaft, the seat includes a bottom plate, a bracket disposed on the plate and for disposing the motor, and shock-absorbing connectors respectively connecting with the plate and the bracket, each of the shock-absorbing connectors includes a pillar disposed on the plate, and a buffer spring sleeved on the pillar and with two ends respectively contacting the plate and the bracket, the buffer spring makes the bracket suspended relative to the plate, the clamp includes a shaft joint directly connected to the output shaft, and two arms respectively assembled on the shaft joint, the shaft joint and the output shaft are disposed coaxially, and an inclination angle less than 180 degrees is provided between the two arms and the shaft joint.

A dual-axis mixer for food products includes a product holder that is configured to hold a sealed product cup containing a food product to be mixed. The mixer has a primary axis of rotation about a central axis, and a secondary axis of rotation radially offset from the central axis. In doing so, the secondary axis positioned to rotate around the primary axis. Furthermore, the product holder is located at the secondary axis and is configured to rotate about the secondary axis. Rotation about the primary axis applies centripetal force to the food product, and the secondary axis rotates the product holder to churn the food product within the product cup.

A method for mixing, milling, and coating a plurality of constituents comprises placing the constituents in a container that includes a cylindrical inner surface; applying a first vibration to the container such that a motion of the vibration is parallel to a longitudinal axis of the container; and applying a second vibration to the container such that the motion of the vibration is not parallel to the longitudinal axis of the container.

A blending machine, for homogenizing materials deposited within an intermediate bulk container (IBC), includes: a frame; a drive motor; a clamp disk rotatably supported by the frame and coupled to the drive motor to drive disk rotation; first and second jaw clamps movably mounted to the frame; and a drive mechanism to drive the jaw clamps to translate toward each other and rotatably secure the IBC's boom to the rotatable clamp disk. A clutch, a torque limiter, and a limit switch limit the pressure applied by the clamps, and the extent of their travel to optimize clamping and rotatability. The blending machine is moveably mounted to a pedestal, and elevated by an actuator. A blending bar within the IBC is coupled through the boom to the clamp disk, and driven to rotate to blend the materials, in addition to mixing by rotation of the ICB.

Disclosed is an apparatus and method for providing asymmetric oscillations to a container. The container may include a fluid, a particle, and/or a gas. A vibration driver attached to the container provides asymmetric oscillations. A controller connected to the vibration driver controls an amplitude, frequency, and shape of the asymmetric oscillations. An amplifier amplifies the asymmetric oscillations in response to the controller. A sensor disposed on the vibration driver provides feedback to the controller.

A blending machine, for homogenizing materials deposited within an intermediate bulk container (IBC), includes: a frame; a drive motor; a clamp disk rotatably supported by the frame and coupled to the drive motor to drive disk rotation; first and second jaw clamps movably mounted to the frame; and a drive mechanism to drive the jaw clamps to translate toward each other and rotatably secure the IBC's boom to the rotatable clamp disk. A clutch, a torque limiter, and a limit switch limit the pressure applied by the clamps, and the extent of their travel to optimize clamping and rotatability. The blending machine is moveably mounted to a pedestal, and elevated by an actuator. A blending bar within the IBC is coupled through the boom to the clamp disk, and driven to rotate to blend the materials, in addition to mixing by rotation of the ICB.

A pronged clamp apparatus for attaching a soda bottle to a home use carbonation machine, the apparatus includes a pronged clamp to receive the bottle, at a non-upright position prior to carbonation, the bottle having a neck ring, to attach the bottle to the carbonation machine when a user moves said bottle towards an upright position; a locking mechanism to lock the bottle to the carbonation machine via the neck ring in the upright position during carbonation; and an interlock operative within the locking mechanism utilizing the downward movement of the bottle under pressure to prevent the unlocking of the locking mechanism when there is excess pressure in the bottle.