Disclosed herein are techniques and methods for dispersing a volume of gas in a beverage contained in an unpressurized container.

A bottled water dispenser is disclosed that includes a water bottle, a cold tank, and an ozone generator, which is fluidly coupled to a Y-connector. The dispenser includes a first tube that is fluidly coupled to a first port of the Y-connector, with the first tube being configured to deliver ozone gas to the cold tank. The dispenser further includes a second tube that is fluidly coupled to a second port of the Y-connector, with the second tube being configured to deliver ozone gas to the water bottle. The ozone gas is effective to sterilize and prevent biofilm formation within the interior areas of the cold tank and water bottle. The dispensers further include an in-line flow restrictor positioned in-line with either the first tube or second tube, which helps balance the flow of ozone that is delivered to the cold tank and water bottle.

Systems, devices, and methods for the delivery of gas bubbles to liquids are generally described. The devices can include a primary conduit comprising a plurality of openings fluidically connecting an internal flow pathway of the primary conduit to an environment outside the primary conduit. The devices may also include, in some instances, a secondary conduit located at least partially within the primary conduit, the secondary conduit configured to redistribute the pressure of the gas delivered to the openings of the primary conduit, and comprising a plurality of openings fluidically connecting an internal flow pathway of the secondary conduit to a portion of the internal flow pathway of the primary conduit outside the secondary conduit. Certain of the gas delivery systems and methods described herein are capable of delivering gas at relatively uniform linear flow velocities across multiple gas outlet openings. Certain embodiments are related to inventive configurations (e.g., spacings and/or sizing) of gas outlet openings in one or more conduits of the gas delivery device (e.g., the primary conduit and/or, when present, the secondary conduit). In addition, some embodiments are related to inventive arrangements for joining a gas delivery device to a vessel, which may be part of for example, a reactor such as a bioreactor. Certain embodiments are related to the orientation of the gas delivery device and/or its components (e.g., during operation).

An ultrasonic cleaning apparatus and method, the ultrasonic cleaning apparatus (10) comprising a tank (12) for in use receiving a cleaning liquid and for receiving an item to be cleaned in a cleaning region (16) thereof, a transducer (21) arranged, when driven, to direct ultrasonic pressure waves into cleaning liquid received in the tank (12) and a controller (30) arranged in use to drive the transducer (21), a gas introducer (40) arranged to in use provide a supply of gas into cleaning liquid in the tank so that macroscopic bubbles of gas are produced wherein the gas introducer (40) provides a plurality of bubble sources distributed below the cleaning region of the tank. The apparatus further comprises an assembly arranged in use to enable movement of the item to be cleaned in the cleaning region.

A diffuser is disclosed and includes a channel with an inner portion having an inlet and an outlet through which a gaseous substance enters and exits the diffuser, respectively. The inner portion includes a first conical section that has an increasing cross-sectional area, taken along a plane perpendicular to a central axis, in a first direction. The inner portion also includes a second conical section that has a decreasing cross-sectional area, taken along a plane perpendicular to the central axis, in the first direction. The second conical section is communicatively coupled with the first conical section. The outer portion includes a first annular section that has an increasing cross-sectional area, taken along a plane perpendicular to the central axis, in a second direction opposite the first direction. The diffuser further includes a plurality of orifices that communicatively couple the second conical section with the first annular section.

A hybrid contact tray for a mass transfer column is provided. The contact tray includes a tray deck for passage of liquid along a liquid flow path thereon. The tray deck has a plurality of orifices for passage of ascending vapor through the tray deck, a cross-current vapor-liquid mixing section having a first portion of the plurality of orifices, and a co-current vapor-liquid mixing section including at least one co-current mixing device associated with a second portion of the plurality of orifices. The tray deck also has features capable of altering liquid head levels with respect to the plurality of orifices such that the liquid head level within the co-current vapor-liquid mixing section is greater than the liquid head level within the cross-current vapor-liquid mixing section.

A process and apparatus is provided which are effective for improving CO mass transfer. The process includes introducing syngas into a reactor vessel through a gas sparger located below a liquid level in the reactor vessel. The syngas being introduced at a flow rate effective for maintaining a pressure inside of the reactor vessel of at least about 1 psig. An agitation energy of about 0.01 to about 12 kWatts/m.sup.3 medium is provided. The process is effective for providing a volumetric CO mass transfer coefficient of about 100 to about 1500 per hour.

Equipment for massive dissolution of gases in liquids via the formation of thin liquid films and the exchange of gases with said films. The equipment provides movement of liquids over great distances via the upward movement of bubbles therein. The equipment can alter the direction of the flow of water, said aspect being useful for the recovery of liquid bodies. In addition to providing a high rate of dissolution of gases in liquids, the equipment is very energy-efficient and has a very large volumetric capacity, thereby being useful for the preservation and/or recovery of liquid bodies, being able, in certain applications, to operate in an energy-autonomous manner. The equipment can be used in situations where energy-efficient dissolution of gases in liquids is desired, such as the preservation and/or recovery of liquid bodies; processes for preserving and/or improving the productivity of aquaculture systems; wastewater treatment systems; and the fixation of gases.

The present disclosure relates to a poly-ionic and molecular filtering and diffuser device, which provides for the emission of gases when used from the inside out, and a separation of suspended matter (e.g., in macro, micro and nano ranges) in liquids for a variety of fluids when is used from the outside inwards. The device may include a central diffuser tube defining a plurality of perforations in its wall to allow passage of gas and liquids, and which is inserted through central holes of a plurality of plates diffusers arranged in a vertical arrangement. This combination may define a plurality of slots by the separations generated therebetween, whereby the gas or the liquid is spread. The diffuser-separating plates are contained between a top compression cap and a lower compression cap through which said central diffuser-collector tube is also inserted. The central diffuser-collector tube includes a threaded lower end, wherein a final lower lid is threaded. Seal elements may be disposed between the upper and lower compression cap and the arrangement of the plurality of diffuser-separating plates.

A hydrogen water generator with warning function includes a container, a gas input port, a handle, a diffusing pipe, a gas output port, and a water port. The gas input port receives gas comprising hydrogen. The diffusing pipe is configured in the containing space and coupled to the gas input port. The gas output port receives the gas comprising hydrogen in the containing space and outputs it to the outside. The water port outputs the water to the outside. The gas comprising hydrogen enters into the water in the containing space to generate hydrogen water and humidified gas comprising hydrogen to be outputted to the outside of the container through the water port and the gas output port respectively. The container emits a first color light when the system is under a normal condition, but emits a second color light when the system is under an abnormal condition.