A water aeration system (10) encases an air pump (60) and a solar power controller (62) in an encasement structure (34) with one or more air permeable sidewalls (42; 44). The encasement structure is mounted at or near a top end of a mounting pole (32). A solar panel (50) is mounted directly or indirectly to the encasement or to the mounting pole at or near the top end of the mounting pole, optionally with screens (80, 82, 84, 86) connected to the backside of the solar panel. An air conduit (20) is threaded through a hollow channel in the mounting pole or structure associated therewith, and then underground and/or under water for joining to an immersed diffuser (12). The system is protected from tampering where the air pump and controller are inside the encasement structure, the solar panel and encasement structure are mounted several feet above the ground surface, the underside of the solar panel is shielded by protective screens, and the conduit between the pump and the diffuser is held inside the mounting pole or structure associated therewith.

First and second concentration measurements are provided in lines for first and second supply liquid lines. A dissolved concentration of gas in the second supply liquid is lower than that in the first supply liquid. In the first and second lines, first ends of branch lines are connected upstream of the concentration measurements. The second ends of the branch lines are connected to a mixing part. By mixing the first and second supply liquids, a processing liquid is generated. Respective flow rates in the branch lines are based on the first and second concentration measurements to set the dissolved concentration of the gas in the processing liquid. Thus, particles or the like can be removed from the processing liquid to be supplied to a substrate, and the dissolved concentration of the gas in the processing liquid can be set with high accuracy.

The present application discloses a ozonated water delivery system which includes at least one contacting device in communication with at least one ultrapure water source configured to provide ultrapure water, at least one ultrapure water conduit coupled to the ultrapure water source, at least one solution in communication with the contacting device and the ultrapure water source via the ultrapure water conduit, one or more gas sources containing at least one gas in communication with at least one of the ultrapure water source, the ultrapure water conduit, and the solution conduit, at least one mixed gas conduit in communication with the at gas source and the contacting device and configured to provide at least one mixed gas to the contacting device, and at least one ozonated water output conduit may be in communication with the contacting device.

The disclosed apparatus, systems and methods relate to devices, systems and methods for mixing particulate matter such as salt with moisture. In various implementations, the mixer is transportable. In various implementations the mixer comprises a hopper, at least one auger, and a mixing housing. Various implementations, additionally include at least one liquid tank.

The efficiency of water disinfection can be significantly increased by supplying the ozone in combination with oxygen to an inlet of a cavitation pump. The ozone and the oxygen are turned into ultra-fine bubbles via cavitation action within the pump, facilitating the dissolution of the oxygen and ozone within the water. The water mixed with the oxygen and the ozone is subsequently supplied to a line atomizer, where the dissolution of the ozone within the mixture is completed. The combined use of the cavitation pump and the line atomizer can lead to a substantially complete dissolution of the supplied ozone within water that needs to be disinfected, allowing to easily achieve the concentration of ozone necessary for water disinfection. Due to this efficiency, the system and method described are highly scalable and suitable for water purification at water purification plants of various sizes.

A vacuum pumping system which comprises a plurality of vacuum pumping arrangements for evacuating a flammable gas stream and exhausting the gas stream through an exhaust outlet. A housing houses the vacuum pumping arrangements and forms an air flow duct for an air flow for mixing with the exhaust gas stream output from the exhaust outlet in a mixing region in the housing. An airflow generator generates an air flow through the air flow duct to cause mixing of air with the flammable gas stream to a percentage of the flammable gas in the air flow lower than the lower flammability limit of the flammable gas. An airflow sensor senses the flow of air for determining if the air flow is sufficient to dilute the flammable gas to lower than said percentage.

A process is described that includes flowing a carrier fluid through a transfer line, feeding polymer pellets into the transfer line at a feed location, measuring a first pressure value of the carrier fluid at a location in the transfer line upstream of the feed location, measuring a second pressure value of the carrier fluid and polymer pellets at a downstream location in the transfer line which is downstream of the feed location, and determining a mass flow rate of the polymer pellets flowing in the transfer line based on a differential pressure between the first pressure value and the second pressure value.

Described in detail herein is an automated paint mixing system. The paint mixing system includes a mobile device which can receive an input associated with a color of a paint. The mobile device can transmit the input associated with a color to a first computing system. The first computing system can receive the input associated with a color. The first computing system retrieve an identifier associated with the color based on the input. The first computing system can transmit the identifier associated with the color to a second computing system. The second computing system can instruct a paint dispenser to mix and generate a specified amount of paint of the requested color based on the received identifier. The second computing system can instruct a 3-D printer to fabricate a three-dimensional container configured to store the generated paint. The paint dispenser can deposit the generated paint in the three-dimensional container.

A domestic beverage carbonator for carbonating a liquid in a bottle comprising temperature and pressure sensors that communicate with processor to improve the carbonation process. The device further comprises a CO2 cylinder coupling and a cylinder discharge valve, an exhaust valve, a fill head and a user interface. The user interface further comprises user controls and a graphic display and the fill head has a pressure sensor to sense a pressure in the attached bottle and communicate a pressure signal to the processor and the processor uses the pressure signal to regulate the cylinder valve and the exhaust valve.

A valve comprising a valve spindle housing located in the side of the chamber and including a first fluid inlet and a first fluid outlet, and a cylinder open along a portion of a longitudinal axis of the cylinder and rotatably mounted in the valve spindle housing. The cylinder is positioned in one position so that the cylinder completely obstructs the valve spindle housing outlet, not allowing any fluid to pass around the cylinder. The cylinder walls are solid except for having openings through a portion of the cylinder, so that when rotated to a closed position, the solid portion of the cylinder fully obstructs the valve spindle housing outlet, and when rotated to an open position, the first fluid can pass into the inside of the cylinder and then through the openings and out of the valve spindle housing.