A method and system are provided for preparing micro-ingredient feed additives for use in designated feed rations. A micro-ingredient system of the invention includes a plurality of bins that store designated micro-ingredients therein. A master controller of the delivery system provides signals to control system components based on programmed commands corresponding to micro-ingredient batches to be prepared. Slide gate mechanisms are used to prevent loss of micro-ingredients delivered to a receiving receptacle of the system. During delivery of the micro-ingredients to the receptacle and during processing, the micro-ingredients can become airborne and subsequently lost. The slide gate mechanisms also provide controlled access to the receiving receptacle to prevent system errors such as contamination of ingredients in the receptacle, or improper batching of a prescribed micro-ingredient mixture to be delivered to a designated feed ration.

The invention relates to a capsule (3) for producing a composition, particularly for dental care, comprising an enclosure (6) provided with at least two compartments (8), the number of compartments corresponding to the number of components to be mixed, and at least one wall (10) for isolating the components, said wall (10) being provided to isolate the components form each other in storage mode, and to allow fluidic communication between the compartments (8) in mixing mode, said capsule also comprising a driving rod (2), one end of which is designed in compliance with the ISO 1797 standard, for removable attachment to a hand-held part (1).

A handheld apparatus for mixing food product comprising a manual input and a drive structure comprising a drive input, wherein the manual input is operatively connected to the drive input to actuate the drive means, the drive means further comprising first and second drive outputs operatively coupled to the drive input and being arranged to simultaneously rotate the first drive output in a first direction and rotate the second drive output in a second direction and rotate both drive outputs in the second direction about the central axis of the apparatus, such that the number of revolutions completed by the first drive output is less than the number of revolutions completed by the second drive output each time the drive outputs complete a revolution about the central axis.

A method of controlling a portable appliance includes measuring an input current supplied to a motor of the portable appliance and measuring a rotational speed of a shaft of the motor. The method also includes determining a current limit based on the rotational speed of the shaft using a substantially continuous function which relates a domain of rotational speeds to a range of current limits. The method further includes reducing, when the input current exceeds the current limit, the rotational speed of the shaft incrementally along the substantially continuous function until the input current is approximately equal to the current limit.

The present invention is related to a system and method for controlled manufacturing of mono-disperse microbubbles. According to the invention, the mono-disperse nature of the collection of generated microbubbles can be improved by releasing the pressurized gaseous medium used in the system using release valve units. This further allows the system to be embodied as a portable system. In turn, the operator of an ultrasound imaging apparatus may use the system according to the invention to generate microbubbles on a patient-by-patient basis.

A Container is disclosed with a stirrer device suitable to be installed on machines for dispensing fluid products. The container comprises a tank with a particular configuration defined by two cylinders each having a respective longitudinal axis, wherein the distance between two of the longitudinal axes is less than the diameter of a cylinder, and in which two stirrer units are comprised, coaxial to the cylinders of the tank. The stirrer units have elements that have a radial dimension a little less than the radius of the cylinders and are disposed along the substantial entirety of the longitudinal extension of shafts rotating axially, said shafts not having around them a zone not spatially affected by a stirrer element attached to said corresponding shaft.

A system for blending solutions and a buffer solution is disclosed. In this system a switch valve is present capable of flowing one or more solutions, a low pressure pump for pumping the one or more solutions through the switch valve and a T-joint capable of receiving the one or more solutions through the low pressure pump and blending the one or more solutions with a buffer solution. A high pressure pump is present for collecting a blended solution.

[Object] To provide a mixing device capable of accurately mixing a solution in a multi-well plate.

[Solving Means] A mixing device 1 is configured to be attachable to a multi-well plate 30 and includes a casing 100, a plurality of stirrers 11, a plurality of motors 12 as a drive portion, and a mounting portion 16. The casing 100 includes a main surface portion 101 facing an upper surface 301 of the multi-well plate 30. The stirrers 11 protrude from the main surface portion 101 toward wells 31 of the multi-well plate 30. The motors 12 are disposed to the casing 100 and rotate the stirrers 11 about axes thereof. The mounting portion 16 is provided to the casing 100 and is mounted to the multi-well plate 30 to position the casing 100 on the multi-well plate 30.

A blender container and puck assembly is generally described. The puck assembly may include a retainer nut that affix a blade assembly to the blender container. The puck assembly is not directly fastened to the container. The puck assembly may include an identification tag that interacts with a transponder.

Systems and methods for dissolving ozone gas in a liquid. An embodiment can comprise a tank having an upper region, a lower region, and a discharge outlet, all disposed in a specified geometry. A pump can be coupled with a liquid inlet in order to receive a liquid therefrom and to deliver the liquid via a pipe to the upper region of the tank. The pump can be coupled with the lower region of the tank in order to receive the liquid from the tank and to recirculate the liquid to the upper region of the tank. The apparatus can include an ozone inlet to receive ozone into the tank. The ozone inlet can comprise a venturi inlet disposed on the pipe downstream of the pump. The liquid can be released from the tank and depressurized, thereby providing for the ozone to emerge from the liquid as gas bubbles. The released liquid can be selected for a two-stage gas and aqueous cleaning process.