An ion-exchange resin regeneration system includes: salt water flowing means that flows an aqueous sodium chloride solution or an aqueous potassium chloride solution into a container storing ion-exchange resin; and hard water component crystallizing means that crystallizes and removes hard water components containing metal ions from drained water arising from the ion-exchange resin through which the aqueous sodium chloride solution or the aqueous potassium chloride solution has flowed.

A multi tank water softener system in which multiple softeners can be selectively operated in parallel, alternating, or in series in either order. The system reduces risk of Legionella and pathogen grown while also reducing salt usage by up to 40%.

Provided is a water softening system not requiring electrical or electronic actuation in which an ion regeneration process of a resin bed contained in a water treatment tank is hydraulically actuated by a sensing device held at a top of the water treatment tank with a body of the sensing device being partially embedded in the resin bed to detect ion depletion of the resin bed.

Provided is a water softening system not requiring electrical or electronic actuation in which an ion regeneration process of a resin bed contained in a water treatment tank is hydraulically actuated by a sensing device held at a top of the water treatment tank with a body of the sensing device being partially embedded in the resin bed to detect ion depletion of the resin bed.

The present invention relates to a liquid treatment system having a sensor comprising a body, the body having a sensing material disposed therein, the sensing material being subject to a change in size in response to a composition of a liquid flowing therethrough; an actuating means disposed within the body and associated with the sensing material; wherein the actuating means is movable between a first position and a second position in response to the change in size of the sensing material to thereby mechanically actuate a switch member, such that when the actuating means is in the first position, flow of an actuating stream of the liquid is allowed by the switch member to thereby hydraulically actuate operation of the liquid treatment system; and when the actuating means is in the second position, flow of the actuating stream of the liquid is prevented by the switch member.

The present invention relates to a liquid treatment system having a sensor comprising a body, the body having a sensing material disposed therein, the sensing material being subject to a change in size in response to a composition of a liquid flowing therethrough; an actuating means disposed within the body and associated with the sensing material; wherein the actuating means is movable between a first position and a second position in response to the change in size of the sensing material to thereby mechanically actuate a switch member, such that when the actuating means is in the first position, flow of an actuating stream of the liquid is allowed by the switch member to thereby hydraulically actuate operation of the liquid treatment system; and when the actuating means is in the second position, flow of the actuating stream of the liquid is prevented by the switch member.

Water softening device includes water softening tank and neutralizing tank. Water softening tank softens raw water containing a hardness component by weakly acidic cation exchange resin. Water softening tank includes first water softening tank and second water softening tank. Neutralizing tank neutralizes the pH of softened water that has passed through water softening tank by weakly basic anion exchange resin. Neutralizing tank includes first neutralizing tank and second neutralizing tank. Water softening device is configured to cause raw water containing a hardness component to flow through first water softening tank, first neutralizing tank, second water softening tank, and second neutralizing tank in this order.

Water softening device includes water softening tank and neutralizing tank. Water softening tank softens raw water containing a hardness component by weakly acidic cation exchange resin. Water softening tank includes first water softening tank and second water softening tank. Neutralizing tank neutralizes the pH of softened water that has passed through water softening tank by weakly basic anion exchange resin. Neutralizing tank includes first neutralizing tank and second neutralizing tank. Water softening device is configured to cause raw water containing a hardness component to flow through first water softening tank, first neutralizing tank, second water softening tank, and second neutralizing tank in this order.

A self-regenerating ion-exchange water softener has an inlet connectable to a source of softenable water under pressure, a resin chamber connected thereto, and an outlet connected to the resin chamber. A salt chamber is located above the resin chamber and contains a water-soluble salt for regenerating the resin. A chamber connection allows controlled downward flow of fluid from the salt chamber to the resin chamber. A first normally-open pressure-sensitive valve closes in response to increased water pressure in the resin chamber, and normally permits a downward fluid flow from the salt chamber to the resin chamber. A passageway permits pressurized water to flow upwardly from the resin chamber to a point above the high-water mark of the salt chamber to generate salt solution for contacting and regenerating the resin, and has a discharge control above the high-water mark.

A self-regenerating ion-exchange water softener has an inlet connectable to a source of softenable water under pressure, a resin chamber connected thereto, and an outlet connected to the resin chamber. A salt chamber is located above the resin chamber and contains a water-soluble salt for regenerating the resin. A chamber connection allows controlled downward flow of fluid from the salt chamber to the resin chamber. A first normally-open pressure-sensitive valve closes in response to increased water pressure in the resin chamber, and normally permits a downward fluid flow from the salt chamber to the resin chamber. A passageway permits pressurized water to flow upwardly from the resin chamber to a point above the high-water mark of the salt chamber to generate salt solution for contacting and regenerating the resin, and has a discharge control above the high-water mark.