Provided according to an aspect of the invention may be an apparatus for manufacturing cosmetic, which includes a housing which forms an outer appearance; an internal phase container which is provided in the housing, and which stores internal phase fluid excluding surfactant; an external phase container which is provided in the housing, and which stores external phase fluid excluding surfactant; a channel unit which generates emulsion by mixing the internal phase fluid provided from the internal phase container and the external fluid provided from the external phase container; and an operative unit which provides external force required to form and discharge emulsion at the channel unit by manipulation of a user.

An apparatus and process for preparing a water/diesel oil micro-emulsion including a diesel oil feeding unit, an emulsifying composition feeding unit, a water feeding unit, and a mixing tank in fluid communication therewith. A duct extends along main direction (X-X) and presents an inlet opening, outlet nozzle, and a cone shaped septum coaxial with respect to the main direction (X-X) and tapers towards the outlet nozzle. A plurality of holes is in the conical wall of the septum and a plurality of lamellae is arranged in the duct downstream of the septum. The plurality of lamellae creates a plurality of small chambers. Holes and the small chambers delimit a labyrinth passageway for liquid flowing through the duct towards the outlet nozzle. A batch is recirculated through the mixing tank and a conduit including a mixing device and then the fuel micro-emulsion batch is discharged.

A method for encapsulating active ingredients in liposomes having an active ingredient solution encapsulated with a bilayer composed of two monomolecular layers of amphiphilic compounds comprises: (a) providing the active ingredient solution; (b) providing an emulsion by emulsifying the active ingredient solution in a first liquid in the presence of the amphiphilic compound; (c) providing a liquid phase; (d) contacting the emulsion with the liquid phase to form a phase boundary; and (e) centrifuging the emulsion and the liquid phase that are in contact with one another via the phase boundary, wherein, on passage of the phase boundary, the amphiphilic compound enriched there is added onto the monomolecular inner layer to form a monomolecular outer layer, in order to create the bilayer.
The first liquid of the emulsion is chosen such that the solubility of the amphiphilic compound in the first liquid is not more than 1×10.sup.−4 mol/l.

A method of generating bubbles of a first fluid in a second fluid, the method comprising: flowing a stream of the second fluid through a microfluidic channel; injecting a stream of the first fluid into the microfluidic channel through an aperture such that bubbles of the first fluid form in the second fluid; and sonicating the microfluidic channel with ultrasound so as to cause the bubbles formed at the aperture to divide.

The disclosure discloses a milk protein concentrate-based microencapsulation wall material and microcapsules, and belongs to the technical field of microcapsule preparation. In the disclosure, liquid or solid microcapsules are prepared by performing cation exchange treatment on milk protein concentrates, and then using the treated milk protein concentrates as a wall material. The prepared microcapsules have good physical and chemical stability during storage, and are suitable for protecting active functional factors and to be applied in the fields of food, medicine, health care products, cosmetics, daily chemicals and the like.

A system and method for producing an oil-in-water (“O/W”) emulsion performs or includes the steps of: a) providing an oil phase and a water phase, b) premixing the oil phase and the water phase to form an O/W pre-emulsion, and c) homogenizing the O/W pre-emulsion to form an O/W emulsion by at least one counter-jet disperser.

Methods and devices for formulating scented nanoemulsions and dispersing one or more scents is disclosed. In some embodiments, the method includes providing a first mixture including water and a water surfactant, providing a second mixture including a fragrance material and an fragrance surfactant, mixing the first and second mixtures to create a temporary emulsion, and performing one or more high-energy homogenizations to the temporary emulsion until one or more desired physical properties of a resulting nanoemulsion are obtained. In some embodiments, the one or more high-energy homogenizations includes microfludization, sonication, and high-shear mixing. In some embodiments, the resulting nanoemulsion may thereafter be dispersed as a scent via an aerosolizing device. In some embodiments, the aerosolizing device may disburse scents in response to actions and/or events experienced in an AV/AR system.

What is proposed is an emulsifying system for an internal combustion engine, wherein the emulsifying system comprises an emulsifying device for producing a water-fuel emulsion and an injector for injecting the water-fuel emulsion in a combustion chamber, the emulsifying device being arranged within the injector. Also proposed is an emulsifying method for preparing a water-fuel emulsion for an internal combustion engine, wherein fuel is pressurized in a fuel pressure accumulator and water is pressurized in a water pressure accumulator and fed separately to an injector for injecting the fuel and water into an associated combustion chamber, and/or fuel and water are emulsified by means of an emulsifying device that is integrated into an injector.

An apparatus for preparing a water/diesel oil micro-emulsion comprises a diesel oil feeding unit (2), an emulsifying composition feeding unit (3), a water feeding unit (4), a mixing tank (5) in fluid communication with the diesel oil feeding unit (2), with the emulsifying composition feeding unit (3) and with the water feeding unit (4). A mixing device (22) is operatively connected to the mixing tank (5). The mixing, device (22) comprises a duct (39) extending along a main direction (X-X) and presenting an inlet opening (40) and an outlet nozzle (4). A cone shaped septum (60) is placed in the duct (39), coaxial with respect to the main direction (X-X) and tapering towards the outlet nozzle (41). The cone shaped septum (60) is provided with a plurality of holes (65) made through its conical wall (63). A plurality of lamellae (76, 80) are arranged in at least a portion of the duct (39) placed downstream of the cone shaped septum (60). The plurality of lamellae (76, 80) divides said portion in a plurality of small chambers (77, 82) and are provided with through holes (78, 81). The holes (78, 81) and the small chambers (77, 82) delimit a labyrinth passageway for the liquid flowing through the duct (39) towards the outlet nozzle (41). The water/diesel oil micro-emulsion is obtained by recirculating a batch contained in the mixing tank (5) and. comprising the diesel oil, the emulsifying composition and the water through a recirculation conduit and through the mixing device (22).

A method for optimizing a Hegman rating of a diluted emulsion including adjusting the shear work in the dilution mixer, wherein the adjusting the shear work may comprise raising or lowering the shear work; adjusting the temperature of the concentrated and/or diluted emulsion; if not earlier added, adding a basic aqueous solution and/or dispersing agent; adding one or more other additives; and/or adjusting the amount of any additive, basic solution or surfactant solution is provided. Also provided are diluted emulsions produced thereby and coatings made from the diluted emulsions.