An individual frozen drink dispenser includes a housing having a base configured to support a blender cup, a dispensing chamber disposed above the blender cup and configured to support a frozen beverage container containing frozen ingredients suitable for preparing a frozen drink, at least one dispensing mechanism configured to move from a pre-dispense position to a dispense position in which the dispensing mechanism drives the frozen ingredients from the frozen beverage container into the blender cup, and a drive mechanism coupled to the housing and configured to drive the movement of the dispensing mechanism from the pre-dispense position to the dispense position. A method of preparing a frozen drink is further disclosed.

A multifunctional C.sub.4F.sub.7N/CO.sub.2 mixed gas preparation system is disclosed. The C.sub.4F.sub.7N heat exchanger is used to heat and vaporize C.sub.4F.sub.7N input through the C.sub.4F.sub.7N input port; the CO.sub.2 heat exchanger is used to heat and vaporize CO.sub.2 input through the CO.sub.2 input port; the C.sub.4F.sub.7N/CO.sub.2 mixing pipeline structure is used to mix the heated C.sub.4F.sub.7N and heated CO.sub.2, and the C.sub.4F.sub.7N/CO.sub.2 mixed gas output pipeline structure is used to output the C.sub.4F.sub.7N/CO.sub.2 mixed gas. The C.sub.4F.sub.7N/CO.sub.2 mixing pipeline structure comprises a C.sub.4F.sub.7N/CO.sub.2 dynamic gas preparation pipeline structure and a C.sub.4F.sub.7N/CO.sub.2 partial pressure mixing pipeline structure; the C.sub.4F.sub.7N/CO.sub.2 partial pressure mixing pipeline structure includes partial pressure mixing tanks for mixing the CO.sub.2 and the heated C.sub.4F.sub.7N of certain pressures; and a plurality of partial pressure mixing tanks are arranged in parallel. A multifunctional C.sub.4F.sub.7N/CO.sub.2 mixed gas preparation method is also disclosed.

A system that provides for simultaneous thermal regulation of both components of a two-component system, while maintaining their separation prior to introduction into a conventional static mixer element, in order to assure that the mixed fluid, when dispensed, is at the optimal temperature and viscosity. The thermal capacity can be adjusted by altering the configuration to increase or decrease the thermal transfer area as required for each specific application.

A feedstock delivery system for injection molding includes a vessel unit that includes a vessel with an internal volume and an inlet for receipt of a feedstock. First and second dispensing units are alternatively connectable to the vessel unit and each include first and second ends, first and second valves, and a buffer chamber. The first end is connectable to the dispensing unit such that the buffer chamber is in communication with the internal volume of the vessel. The second end is connectable to an injection mold and defines an outlet of the feedstock delivery system. The outlet is in communication with the buffer chamber, and the buffer chamber is positioned between the first and second valves. The buffer chamber of the first dispensing unit defines a first chamber volume, and the buffer chamber of the second dispensing unit defines a second chamber volume greater than the first chamber volume.

Disclosed is a system for production of a cosmetic product including: at least one first single-use packaging unit including a preset quantity of a first phase of a cosmetic product, at least one second single-use packaging unit including a preset quantity of a second phase of a cosmetic product, a machine including a mixer inside of which the mixture of the preset quantity of the first phase and the preset quantity of the second phase is done automatically in order to end up with a cosmetic product directly consumable by the end consumer. The mixing is done in a manner such that neither the first phase nor the second phase are in direct contact with any part of the mixer which is not single use, thus avoiding dirtying the mixer.

A generative scent design system may used to create unique and custom scents (fragrances, perfumes) in real time based upon input from a user. The system may also be utilized for creating other unique and custom formulations of beverages, alcohols, juices, medications, lotions, shampoos and other products, etc. The generative scent design system may have an input receiver, an input processor, a plurality of scents, a plurality of dispensers, a conveyor belt, a plurality of motion sensors, a container, a label, a cap, and, at least one sound output device.

A vehicle exhaust system includes a conduit defining an exhaust gas flow path extending along a center axis, and wherein the conduit includes a doser opening. An exhaust gas aftertreatment component is positioned downstream of the conduit and at least one doser is configured to inject fluid into the conduit through the doser opening. A heating element pre-heats the fluid prior to mixing with exhaust gas. A perforated pipe is positioned within the exhaust gas flow path to surround the fluid injected by the doser.

A system includes a source, a detector, and a controller. The source is configured to emit electromagnetic energy toward two plies of film. A portion of the emitted electromagnetic energy is within a range of wavelengths. The detector is arranged to detect electromagnetic energy propagating away from the two plies of film. The detector detects electromagnetic energy within the range of wavelengths and generates signals indicative of intensity of detected electromagnetic energy. The controller controls operation of the foam-in-bag system based the signals from the detector. The film is transmissive of electromagnetic energy in the range of wavelengths. When dispensed between the two plies of film, one or both of foaming chemical precursors or foam formed from a reaction thereof is opaque to electromagnetic energy in the range of wavelengths.

A system includes a dispenser, first and second feed lines, and heating zones. The dispenser dispenses a first chemical precursor and a second chemical precursor. The first feed line permits flow of the first chemical precursor from a first source to the dispenser. The second feed line permits flow of the second chemical precursor from a second source to the dispenser. The heating zones are located along the first and second feed lines. The heating zones include a first heating zone located around a first portion of the first feed line and a second heating zone located around a first portion of the second feed line. The first heating zone and the second heating zone are independently controllable to independently control temperature around the first portion of the first feed line and temperature around the first portion of the second feed line.

A system for opening and closing a mixing manifold includes a drive motor, a cam plate, and a valving rod connector. The drive motor imparts movement in first and second directions. Movement imparted in the first direction causes the cam plate to move linearly in a third direction and movement imparted in the second direction causes the cam plate to move linearly in a fourth direction. Movement of the cam plate in the third direction causes the valving rod connector to move linearly in a fifth direction and movement of the cam plate in the fourth direction causes the valving rod connector to move linearly in a sixth direction. Movement of the valving rod connector in the fifth direction causes retraction of a valving rod of the mixing manifold and movement of the valving rod connector in the sixth direction causes extension of the valving rod.