To provide a portable hydrogen-water generating pot that can generate highly concentrated drinkable hydrogen water anytime and anywhere in a short amount of time by using not only drinking water but also water or liquids, such as coffee, that have water as their major ingredient as raw water, wherein the portable hydrogen-water generating pot comprises a vessel's main body 1 made of a transparent cylindrical member 1a etc.; a fixed-quantity water supply means 2 provided in the lower part's upper layer block 1b located in the lower part of the vessel's main body, the fixed-quantity water supply means 2 supplying a certain quantity of water contained in the vessel's main body 1 to a chemical tank 6 created in the lower lid 1c of the lower part; a gas passage 4, equipped with a check valve 3, also provided in the lower part's upper layer block 1b, the gas passage 4 allowing hydrogen gas generated in the chemical tank 6 to move to the vessel's main body 1; a chemical tank 6, for containing a hydrogen-generating agent 5, arranged in the lower lid 1c that forms the lower layer of the lower part of the vessel's main body 1; an upper part block that forms the discharge port part 7 located in the upper part of the vessel's main body 1; and a lid 9, equipped with a pressure reducing valve 8, detachably and externally attached to the discharge port part 7.

There is set out highly efficient processes for the production of alkaline spring waters. The processes are designed to minimize the use of the additive alkaline formulations used to create the alkalinity in the spring waters and the use of a maximum amount of non-purified spring water in the formulation of the final alkaline spring water product. This is accomplished by dividing the input spring water into at least two portions. One portion undergoes a purification process and the other is not purified. Each portion is tested in increments for the amount of alkaline formulation needed to attain a pH of at least about 10 and designated potassium ion and sodium ion contents. From the testing the amount of the purified spring water and the amount of non-purified spring water needed to be combined to yield a pH of at least about 10 and the designated potassium ion and the sodium ion contents is calculated. It is desired to use a minimum of alkaline formulation to achieve the set Ph and potassium and sodium ion concentration. In this way the more costly components of the alkaline formulation and the purified spring water can be minimized, but yet the taste and stability maintained over a period of time. The processes apply to waters from a single spring and from a plurality of springs.

Chemically oxidizing a wide range of targeted contaminants in soils, sludges, groundwater, process water, and wastewater and assisting in the eventual (over time) biological attenuation of the contaminants utilizing persulfates activated by trivalent metals, such as ferric iron. The use of trivalent metal activated persulfate results in a chemical oxidation process that yields degradation compounds which facilitate further attenuation via biological processes.

Methods and systems are provided for producing ionized alkaline solutions (e.g. ionized alkaline water) that exhibit long-term stability when stored at room temperature.

A dosing assembly comprising: a water sample inlet; a water sample outlet; a chemical analyzer in fluid communication with the water sample inlet and outlet; a chemical injector comprising a hollow body having an inlet and an outlet; and a motive flow line comprising a hollow body having a water inlet, a fluid outlet, and a chemical inlet positioned between the water inlet and fluid outlet, wherein the outlet of the chemical injector is connected to the chemical inlet of the motive flow line. A treatment delivery system is also disclosed.

Implementations of this disclosure are directed to systems, devices and methods for monitoring parameters associated with a body of liquid. In one embodiment, a device includes a container configured to be partially submerged in a liquid and includes sensors disposed within a submerged portion of the container to measure parameters associated with the liquid. An electronic component disposed within an unsubmerged portion of the container transmits information related to the parameters based upon which one or more actions related to treatment of the body of liquid are suggested.

An apparatus for producing a composition that includes nano-bubbles dispersed in a liquid carrier includes: (a) an elongate housing comprising a first end and a second end, the housing defining a liquid inlet, a liquid outlet, and an interior cavity adapted for receiving the liquid carrier from a liquid source; and (b) a gas-permeable member at least partially disposed within the interior cavity of the housing. The gas-permeable member includes an open end adapted for receiving a pressurized gas from a gas source, a closed end, and a porous sidewall extending between the open and closed ends having a mean pore size no greater than 1.0 μm. The gas-permeable member defines an inner surface, an outer surface, and a lumen. The housing and gas-permeable member are configured to form a composition that includes the liquid carrier and the nano-bubbles dispersed therein.

The present application provides a bottling system for dispensing water with added ingredients into a container. The bottling system includes a distillation station for distilling a flow of the water, an ionization station for raising the pH of the flow of water, one or more ingredient injection stations to add the ingredients into the flow of water, and a filling station for filling the container with the flow of water with the added ingredients.

A method of maintaining a safe free chlorine level in a body of water for recreational use where the free chlorine level at a harmful level comprises determining if the free chlorine level in the body of water is above a safe level and adding sufficient DMH to the body of water to bring the free chorine down to a safe level.

Implementations of this disclosure are directed to systems, devices and methods for monitoring parameters associated with a body of liquid. In one embodiment, a device includes a container configured to be partially submerged in a liquid and includes sensors disposed within a submerged portion of the container to measure parameters associated with the liquid. An electronic component disposed within an unsubmerged portion of the container transmits information related to the parameters based upon which one or more actions related to treatment of the body of liquid are suggested.