Various systems, devices, and methods of venting a chamber in a beverage carbonation system 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 can include a venting system configured to vent a mixing chamber of the carbonation system in which a carbonated fluid is configured to be formed. The venting system can be configured to provide flow restriction configured to provide a restriction on a vent flow path through which the mixing chamber is vented.

The present invention provides a dust removal system for a chimney of a mixer. The system includes a dust removal water tank and a first pipeline. One end of the first pipeline is communicated with an outlet of the chimney at a tail of the mixer, and the other end is inserted into the dust removal water tank. A water inlet and a water outlet are provided in the dust removal water tank. An exhaust port for discharging filtered gas is provided in an upper part of the dust removal water tank. The system does not need additional power, and is energy-saving and environmentally friendly. Water vapor discharged facilitates the sedimentation of dust particles in the mixer, thereby reducing loss of raw material mixture, making sintering quality more stable and solving a problem that gas discharged in prior arts contains more powder and pollutes the environment.

The present invention involves a drum assembly including a barrel having a top and a bottom. The top has a valve port and a mixer port. The bottom has a downwardly conical shape. The barrel interior storage extends from the top to the conical center of the bottom for extracting liquid from the barrel. The mixer port supports a mixer tool having a shaft with mixing paddles extending into the interior of the barrel.

A tumble drum for recovering at least some flavoring material dispensed onto food portions processed within the tumble drum, the tumble drum having an interior mixing chamber, a first set of apertures in a wall of the tumble drum, a circumferential cavity surrounding the interior mixing chamber, an exterior section in the wall, and a second set of apertures in the exterior section, wherein a receiver coupled to a suction source can engage the exterior section to draw air from within the interior mixing chamber, through the first set of apertures, into the circumferential cavity, through the second set of apertures and into the receiver, and at least some airborne flavoring material is deposited onto food portions through which the air passes on it path. The exterior section may be in an anterior wall surrounding an inlet of the tumble drum or a circumferential portion of the exterior.

Parallel reactor systems for synthesizing materials are disclosed. The reactor systems may be suitable for synthesizing materials produced from corrosive reagents. Methods for preparing materials by use of such parallel reactor systems are also disclosed.

An apparatus for preparing compound dispersoids of hydrophobic nanoparticles and surfactants, comprises a water supply pipeline, a compounding mixing pipeline and an aggregating pipeline; the compounding mixing pipeline comprises an ultrasonic dispersion instrument and a liquid storage tank connected in series into a loop, and a second plunger pump allowing unidirectional circulation of materials is arranged between the ultrasonic dispersion instrument and the liquid storage tank; the water supply pipeline is connected to the top of the ultrasonic dispersion instrument; and the aggregating pipeline is connected to a discharge end of the liquid storage tank.

An apparatus for preparing compound dispersoids of hydrophobic nanoparticles and surfactants, comprises a water supply pipeline, a compounding mixing pipeline and an aggregating pipeline; the compounding mixing pipeline comprises an ultrasonic dispersion instrument and a liquid storage tank connected in series into a loop, and a second plunger pump allowing unidirectional circulation of materials is arranged between the ultrasonic dispersion instrument and the liquid storage tank; the water supply pipeline is connected to the top of the ultrasonic dispersion instrument; and the aggregating pipeline is connected to a discharge end of the liquid storage tank.

A blending machine, for homogenizing materials deposited within an intermediate bulk container (IBC), includes: a frame; a drive motor; a clamp disk rotatably supported by the frame and coupled to the drive motor to drive disk rotation; first and second jaw clamps movably mounted to the frame; and a drive mechanism to drive the jaw clamps to translate toward each other and rotatably secure the IBC's boom to the rotatable clamp disk. A clutch, a torque limiter, and a limit switch limit the pressure applied by the clamps, and the extent of their travel to optimize clamping and rotatabilty. The blending machine is moveably mounted to a pedestal and elevated by an actuator. A blending bar within the IBC is coupled through the boom to the clamp disk, and driven to rotate to blend the materials, in addition to mixing by rotation of the ICB.

A closed-type medicine mixing extraction device for mixing and extracting medicines stored in a first vial and a second vial, respectively, includes a first needle part and a second needle part, which are able to be fitted to the first vial and the second vial, respectively, a connection port to which a syringe is able to be coupled, and a ventilation port through which air is able to enter and exit, wherein the first needle part and the second needle part communicate with each other through a direct communication flow path, the first needle part and the connection port communicate with each other through an extraction flow path, and the second needle part and the ventilation port communicate with each other through a ventilation flow path. Thus, different types of medicines stored in vials, respectively, are able to be hygienically, safely, and rapidly mixed and extracted.

A system for mixing acid and water can include a tank for holding acid, an acid pump for pumping acid out of the tank, an acid flow meter, an acid control valve, a water pump for pumping water, a water flow meter, a water control valve, a flush valve to selectively flush the system with water, and a controller to monitor the flow meters and control the pumps and the valves. The acid control valve and/or the water control valve can be an electronically controlled valve. The flush valve can be an electronically controlled valve to selectively permit water to flow from downstream of the water pump to upstream of the acid pump. The acid control valve, the water control valve, the flush valve, or any combination thereof can be throttled by the controller to control flow therethrough.