A mixing machine configured to receive a receiving device in order to form a mixing machine, the manufacturing apparatus comprising: a support defining a receiving housing, having a first receiving location configured to receive a first deformable capsule and a second receiving location configured to receive a second deformable capsule, the first and second capsules fluidly linked and respectively containing a first formulation and a second formulation, an actuation system movable relative to the support inside the receiving housing, comprising a first actuation member positioned on one side of the receiving housing and movable thereinside, in order to transmit a pressure force on the first capsule, along a first actuation stroke, a second actuation member positioned on another side, preferably an opposite side, of the receiving housing and movable thereinside, in order to transmit a pressure force on the second capsule, along a second actuation stroke, in which the first actuation stroke has a different length from the second actuation stroke.

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.

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.

The subject matter of this specification can be embodied in, among other things, a mixing system that includes a heating assembly configured to heat liquid, and a mixing assembly including a tank defining a cavity and configured to retain liquid, an inlet in fluidic communication with the cavity and configured to receive liquid from the heating assembly, a mixing impeller assembly configured to mix contents of the cavity, an actuator configured to actuate the mixing impeller assembly to mix contents of the cavity, and an outlet in fluidic communication with the cavity and having a valve configured to selectively prevent and permit egress of contents of the cavity.

A generative scent design system has a frame, an input receiver, an input processor, a dispenser, a container, and a filling platform. The dispenser has a dosing station and a storage compartment. The dosing station and the filling platform are attached to the frame. The dosing station has a plurality of pumps. The heating system regulates its associated pump's temperature. The storage compartment has scent vessels that contain a respective scent. Each pump with an inlet and an outlet is associated with a respective heating system and respective scent; in fluid communication through the inlet with the scent vessel containing the respective scent; and configured to dispense its respective scent through the outlet. The container is movably positioned on the filling platform to receive the respective scent from each pump. The input receiver receives data. The input processor calculates the data to determine a formulation of respective scents.

A powder supply method for causing a powder supplied from a top end 70t of a tube 70 to flow down within the tube 70 and be discharged from a bottom end 70b of the tube, in which if M [kg/s] is a supply flow rate of the powder and A.sub.S [m.sup.2] is a cross-sectional area of the bottom end 70b of the tube 70, the following expression is satisfied.

1.5≤(M/A.sub.S)≤135

An exhaust aftertreatment system for use with over-the-road vehicle is disclosed. The exhaust aftertreatment system includes a reducing agent mixer with a mixing can and a flash-boil doser configured to inject heated and pressurized reducing agent into the mixing can for distribution throughout exhaust gases passed through the mixing can.

Shown and described is a device (100) for dosing and/or preparing a mixture of substances, in particular a medium or a buffer, the device (100) comprising: at least one first container (102), which is designed to receive at least one solid component, at least one first dosing device (104) for dosing the at least one solid component, the first dosing device (104) being connected to or can be connected to the first container (102), at least one fluid connection (110, 110′) to connect to at least one second container (103, 103′), which is designed to receive at least one fluid, and/or a fluid line for supplying a fluid, and at least one second dosing device (108, 108′) for dosing the at least one fluid, the second dosing device (108, 108′) being connected or connectable to the second container (103, 103′) or to the fluid line, respectively. the fluid line, wherein the at least one second container (103, 103′) and/or the at least one second dosing device (108, 108′) are replaceable and are developed as disposable articles, and/or wherein the at least one first container (102) and/or the at least one first dosing device (104) are replaceable and are developed as disposable articles.

Improving health and experience of a cosmetic product user, the robotic cosmetic mix bar of the present invention is disclosed. The robotic cosmetic mix bar allows the user to select safe ingredients tailored to their own unique hair and skincare goals. In one embodiment, the robotic cosmetic mix bar contains a robotic arm surrounded by a dispenser and multiple processing stations. Based on a user input indicating a type of cosmetic product and the ingredients to include in the cosmetic product, the robotic arm obtains the desired ingredients from the dispenser and, by transporting the ingredients from one processing station to another, the robotic arm facilitates the processing of the ingredients. The processing of ingredients can include boiling, cooling, mixing, whisking, blending, etc. Within approximately two minutes, the cosmetic product built according to the user specifications is delivered to the user.

Provided is a lubricant, which may include a mixture of alkyl-esterified fatty acids from waste vegetable oil and a C8/C10 fatty acid blend. The C8/C10 fatty acid blend may include a caprylic fatty acid (C8) and a capric fatty acid (C10). Provided is a method of preparing a lubricant, which may include providing alkyl-esterified fatty acids from waste vegetable oil and a C8/C10 fatty acid blend, and mixing them such that a homogeneous lubricant composition forms. Further provided is a water-based mud, which may include an aqueous base solution and a lubricant composition. Further provided is a method off preparing the water-based mud, which may include providing an aqueous base solution and a lubricant composition and mixing them such that the water-based mud forms. Further provided is a method of using a water-based mud, which may include introducing into a wellbore the water-based mud comprising a lubricant composition.