Systems and methods for multi-chambered syringes are described. In some embodiments, a multi-chamber syringe includes a housing with an internal cavity and first and second plungers disposed at least partially within the internal cavity. The first and second plungers are slidably displaceable relative to the housing, and are associated with first and second chambers respectively. A barrier is disposed at least partially between the first and second plungers to form the first and second chambers. The barrier is slidably displaceable relative to the plungers and barrel to selectively place the first and second chambers including first and second materials respectively in fluid communication. When the barrier is displaced, the first and second materials mix in a combined volume of the first and second chambers. Displacing the first plunger, the second plunger, and the barrier may dispense the mixed materials from the combined volume.

A main container and a sub container for mixing cosmetic and a cosmetic product including the same provides a cosmetic product including a first container providing a first storing space which stores a first fluid, and in which fluid can be mixed; a discharging unit which discharges a fluid stored in the first container to the outside; and a second container which can be coupled to the first container, and which can discharge a second fluid stored in the second container to the first storing space. The second container has a storing state to store the second fluid and an open state to discharge the second fluid, wherein the second container to the open state by the discharging unit being coupled to the first container, and wherein as the second container is converted to the open state, the second fluid is discharged to the first storing space.

An emulsification device disclosed herein comprises: an outer tank having a first pressing end and a first exit end; and an inner tank having a second pressing end and a second exit end, wherein the inner tank is disposed inside the outer tank and the second exit end is located closer than the second pressing end to the first exit end, the outer tank is configured to house a first liquid and the inner tank is configured to house a second liquid, the first and second pressing ends are arranged so that one pressure can be applied onto both the first and second liquids, and under the pressure, the second liquid flows out of the inner tank through the second exit end and contacts with the first liquid in the outer tank so that an emulsion droplet comprising the second liquid within the first liquid is formed.

An additive delivery system may incorporate a cartridge system, including a container cap and a reservoir assembly that provides for storage of an additive. The container cap includes a mixing nozzle for mixing of the additive with a base fluid as the base fluid flows from the base fluid container through the cartridge. A one-way valve prevents backflow of base fluid and/or mixed base fluid/additive from an area downstream of the mixing nozzle such that the base fluid supply remains in a pure state.

A portable preparation assembly to prepare liquid cosmetic/cleanser products in a personalised way has a container which is configured to contain a solvent liquid and includes a base wall, a lateral wall and an upper opening opposite to the base wall; a housing seat configured to house a solid cosmetic/cleanser and arranged at least partially inside the container; and a stirring device which is configured to stir the solvent liquid in the container so as to determine at least partial dissolution of the solid cosmetic/cleanser in the solvent liquid and mix the dissolved solid cosmetic/cleanser with the solvent liquid to obtain the liquid cosmetic/cleanser product.

A mixing device serves for producing a powder mixture of a first powder component and at least one second powder component for an additive manufacturing device. The mixing device includes a first container for receiving the first and/or the second powder component, where a discharge opening for discharging the first and/or the second powder component is provided at a lower boundary of the first container, and a second container for receiving the first and/or the second powder component. The second container is designed to be at least partially open towards an upper side. The first and second container each include at least one fluidization zone for introducing a gas into the first and second container. The mixing device further includes a powder conduit that connects to the discharge opening of the first container and is guided into the second container.

A container with two inner chambers (6, 7) running in its longitudinal direction and separated by at least one partition wall. An aerobic adhesive is stored in one inner chamber (6). A hydrophilic, gel-like activator is stored in the other inner chamber (7); a mixing unit can be attached to the front end of the container. The aerobic adhesive is fed to the mixing unit from the first inner chamber (6), and the hydrophilic activator is fed to the mixing unit from the second inner chamber (7), in a specified mixing ratio via a supply device and mixed together there. This mixture is discharged via an outlet opening (13) of the mixing unit.

A device stores, mixes, and applies polymethylmethacrylate bone cement. The device comprises a first container for a first pasty component of the bone cement, a dispensing plunger arranged in the first container such that it can be shifted and serves for pressing the content of the first container out of a dispensing opening, a mixing facility for mixing the content of the first container, whereby the mixing facility is arranged in the first container and the mixing facility can be moved in the first container from outside for mixing, and at least one second container for at least one second component of the bone cement is arranged in or on said first container. The second container can be opened, such that the contents of the first container and second container can be mixed with each other in the first container, whereby at least a boundary surface of the first container is formed by a mobile volume compensation element.

{Problem}

To provide a dissolved hydrogen liquid-discharging pot that makes it easier for a user to use hydrogen water by making the pot capable of discharging or spraying a liquid in which hydrogen is dissolved continuously for a constant period at a prescribed pressure.

{Solution}

The internal pressure of a pressure chamber, the volume of which has been subdivided by an indicator line on a pot body, is maintained with hydrogen, which is generated by a hydrogen-generating agent disposed in a hydrogen-generating section, at a discharge pressure that is sufficient to discharge all of the liquid inside a bottle section while an on-off valve that opens and closes a discharge tube is closed, and when the on-off valve is opened intermittently or continuously, at a pressure sufficient for continuing discharge of the liquid inside the bottle section and performing continuous discharge of dissolved hydrogen liquid until the bottom of the bottle section is reached.

The invention relates to a test set (1) for a photometric measuring device, comprising a mixing container (2) which has a filling opening (3) and comprising a metering container (8) which can be sealingly inserted into the filling opening (3) of the mixing container (2) and which contains a liquid reagent (13) in a closed cavity (9). The cavity (9) has a closure plunger (11), which can be moved axially in the cavity (9), at a first end of the metering container (8), said closure plunger generating a specifiable filling pressure in the reagent (13), and the metering container (8) has a closure membrane (10) at a second metering container and which can be inserted into the mixing container (2). According to the invention, the closure membrane (10) is equipped with a predetermined breaking point (20) which breaks open when the filling pressure is exceeded in a defined manner as a result of an axial movement of the closure plunger (11), said predetermined breaking point (20) of the closure membrane (10) being formed as a linearly extending material taper of the closure membrane (10), wherein the taper is arranged eccentrically in the region of an opening (24) in the base (23) of the substantially cylindrical metering container (8).