A liquid mixture supplying device is provided for mixing a liquid mixture of a liquid and a powder and supplying the liquid mixture to a spray valve for spraying. The device has a structural design consisting of a containing vessel, a driving device, a dip tube and a scraper. The containing vessel is provided for storing the liquid mixture, and the driving device drives the containing vessel to rotate while a scraper disposed on a side of a dip tube is being used for distributing the liquid mixture. The containing vessel is installed in a tiltable external cavity, and a flow barrier is formed on an inner wall of the containing vessel, and the driving device drives the containing vessel to move by a magnetic force or a transmission shaft, so as to achieve the effect of uniform mixing.

A mixing apparatus including a mixing region can have an inlet and an outlet. The mixing region can be operable to couple with a solution housing, thereby defining a mixing chamber. A stem can extend from a surface of the mixing region and the inlet can be disposed at a distal end of the stem. A wing can disposed at a proximal end of the stem and adjacently engaged with the surface of the mixing region and have a leading edge and a trailing edge.

Problem: A mixing device is provided which can solve problems resulting from friction between a vessel and a stirrer, which can generate a circulatory flow even below the stirrer, and which allows a desired number of stirrers to be arranged at desired positions. A discharge device provided with the mixing device, and a discharge method are also provided. Solution: The mixing device includes a stirrer incorporating a magnet, a stirrer holding mechanism that specifies a position of the stirrer by exerting a magnetic force on the stirrer from the lateral side, and a rotation mechanism that rotates the stirrer holding mechanism, wherein the rotation mechanism rotates the stirrer holding mechanism, thereby rotating the stirrer. The discharge device includes the mixing device, and the discharge method is carried out using the discharge device.

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.

Various illustrative systems, devices, and methods of beverage carbonation system flow control are provided. A carbonation system is one example of a treatment system to which the systems, devices, and methods described herein apply. In general, a carbonation system is configured to form a carbonated fluid and dispense the carbonated fluid in a controlled manner. In an illustrative embodiment, the carbonation system is configured to begin dispensing the carbonated fluid with a pressure in a chamber of the carbonation system, in which the carbonated fluid is formed, being above atmospheric pressure. A gas is introduced into the chamber after dispensing has already started via the pressure in the chamber to drive the flow of the carbonated fluid. The gas can be introduced into the chamber according to a predetermined pressure profile.

A mixing apparatus including a mixing region can have an inlet and an outlet. The mixing region can be operable to couple with a solution housing, thereby defining a mixing chamber. A stem can extend from a surface of the mixing region and the inlet can be disposed at a distal end of the stem. A wing can disposed at a proximal end of the stem and adjacently engaged with the surface of the mixing region and have a leading edge and a trailing edge.

A photo-resistor draw device includes a photo-resistor bottle, a sealing cover arranged on an inlet of the bottle, an air tube passing through the sealing cover and being inserted within the photo-resistor bottle, and a photo-resistor draw tube. The photo-resistor bottle further includes a stirring component for stirring the photo-resistors. As the novel photo-resistor draw device includes the stirring component for preventing the high-precision photo-resistor from being subsided. Not only the stability of the color filter products may be enhanced, but also the defects may be eliminated. As such, the yield rate of the products is improved.

The invention relates to a device and method for producing a bone cement paste (54) from a monomer liquid (4) and a cement powder (5). The device includes a cartridge (1) with a cylindrical interior chamber for mixing the parent components, whereby the interior chamber of the cartridge (1) is closed on the front side up to a delivery opening for expelling the bone cement paste (54) from the interior chamber, a delivery plunger (7) which is arranged in the interior chamber of the cartridge (1) and which is supported in a linearly movable manner in the direction of the delivery opening, the cement powder (5), which is arranged in the interior chamber of the cartridge (1) between the delivery opening and the delivery plunger (7), a monomer receptacle (2) with an interior chamber in which a monomer liquid container (3) containing the monomer liquid (4) is contained, whereby in the monomer receptacle (2), a conveying plunger (6) is arranged movable in the longitudinal direction of the monomer receptacle (2), a compressed gas connection (8), which is directly connected or connected via a compressed gas line in a pressure-tight manner with the interior chamber of the monomer receptacle (2), whereby the conveying plunger (6) is arranged between the monomer liquid container (3) and the compressed gas connection (8) or the compressed gas line in the monomer receptacle (2), and a connection (14) which connects the interior chamber of the monomer receptacle (2) and the interior chamber of the cartridge (1) which is permeable for the monomer liquid (4) but impermeable for the cement powder (5), whereby the monomer liquid container (3) is arranged between the conveying plunger (6) and the connection (14).

A dissolved hydrogen liquid-discharging pot 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. 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 present invention is directed to an applicator having an agricultural product mechanical conveying system which transfers particulate material from one or more source containers to application equipment on demand, and meters the material at the application equipment. The conveying system includes a pneumatic agitation system operably connected to the tanks of the applicator to agitate the particulate material disposed within the tanks in order to reduce the formation of agglomerations and/or bridges of particles within the tanks. The pneumatic agitation system includes a number of nozzle connected to each tank that are in turn connected to a pressurized air source and a controller. The controller is operable to selectively cause pressurized air to flow into the tanks through the nozzles to agitate the particulate material positioned therein, thereby breaking up and agglomerations of material within the tanks.