The disclosure is directed at a tank siphon that is used to remove sediment from a bottom of a water storage tank to improve a quality of the collected water. The siphon includes a tube portion having a suction adapter at one end of the tube portion; and a siphon tube receptacle at the other end of the tube portion.

The disclosure is directed at a tank siphon that is used to remove sediment from a bottom of a water storage tank to improve a quality of the collected water. The siphon includes a tube portion having a suction adapter at one end of the tube portion; and a siphon tube receptacle at the other end of the tube portion.

A multi-phase rotor comprising a disk body, an inlet to receive a liquid into the rotor, and at least one outlet configured to expel the liquid from the internal rotor cavity. A flow path is provided between the inlet and the at least one outlet by a liquid intake channel and internal rotor cavity. The rotor is configured to be rotatable about an axis of rotation and a continuous stable vapour cavity is formed in the internal rotor cavity as the rotor rotates above a stable cavity threshold rotational speed.

In an ice maker with a sump below an ice formation device and a pump for recirculating water from the sump to the ice formation device, water can drain through a stand pipe drain. A drain fitting is disposed in relation to a stand pipe such that the drain fitting's upper end is disposed above the top of the stand pipe, its lower end defines a water inlet adjacent the bottom of the sump, and its perimeter wall extends 360 about the stand pipe to define a drain passage extending from the water inlet to the top of the stand pipe. The upper end of the drain fitting defines a siphon release opening. The stand pipe drain can also include a valve for adjusting the drain between an overflow drain configuration and a siphon drain configuration.

In an ice maker with a sump below an ice formation device and a pump for recirculating water from the sump to the ice formation device, water can drain through a stand pipe drain. A drain fitting is disposed in relation to a stand pipe such that the drain fitting's upper end is disposed above the top of the stand pipe, its lower end defines a water inlet adjacent the bottom of the sump, and its perimeter wall extends 360 about the stand pipe to define a drain passage extending from the water inlet to the top of the stand pipe. The upper end of the drain fitting defines a siphon release opening. The stand pipe drain can also include a valve for adjusting the drain between an overflow drain configuration and a siphon drain configuration.

A sediment capture syphon apparatus for capturing sediment from a borrow site is disclosed. The apparatus comprises a containment basin having a containment basin pump valve and a vacuum tank vacuum valve configured to pump water to a vacuum tank. The vacuum tank is connected to an anti-static pressure tank and a backwash tank via one or more valves and conduits. The containment basin is further connected to a separator tank configured to pull the sediment deposits from a submerged filter. A filter assembly is configured to deposit the sediment in the deposited location. The apparatus further includes a buoyancy lift configured to exert a buoyancy lift float mechanism to float deposit and a waterfall tank to receive water flow from the filter assembly by creating pressure. The apparatus is further connected to an electrical power source to power a battery comprising one or more switches via a wire.

A sediment capture syphon apparatus for capturing sediment from a borrow site is disclosed. The apparatus comprises a containment basin having a containment basin pump valve and a vacuum tank vacuum valve configured to pump water to a vacuum tank. The vacuum tank is connected to an anti-static pressure tank and a backwash tank via one or more valves and conduits. The containment basin is further connected to a separator tank configured to pull the sediment deposits from a submerged filter. A filter assembly is configured to deposit the sediment in the deposited location. The apparatus further includes a buoyancy lift configured to exert a buoyancy lift float mechanism to float deposit and a waterfall tank to receive water flow from the filter assembly by creating pressure. The apparatus is further connected to an electrical power source to power a battery comprising one or more switches via a wire.

A vacuum pump for use with a siphon system to continuously purge gases that accumulate in a high point of the siphon system, or for priming the inlet to a pump, or to create vacuum for another purpose. Siphon systems require regular purging of gases when operating for long periods of time. The vacuum pump provides a mechanism that operates in a cycling manner. A first stage of the cycle involves filling a chamber using a pressurised liquid supply, and purging all gases from the chamber. A second stage involves isolating the chamber from the surrounding environment, and then allowing the liquid in the chamber to drain into the siphon system, while at the same time gases from within the siphon system are allowed to enter the chamber. Once the liquid has drained from the chamber, the chamber is isolated from the siphon system, and the liquid filling stage is repeated. Continual cycling of this process can purge the siphon system of gases, or be used to produce a vacuum for other purposes.

A vacuum pump for use with a siphon system to continuously purge gases that accumulate in a high point of the siphon system, or for priming the inlet to a pump, or to create vacuum for another purpose. Siphon systems require regular purging of gases when operating for long periods of time. The vacuum pump provides a mechanism that operates in a cycling manner. A first stage of the cycle involves filling a chamber using a pressurised liquid supply, and purging all gases from the chamber. A second stage involves isolating the chamber from the surrounding environment, and then allowing the liquid in the chamber to drain into the siphon system, while at the same time gases from within the siphon system are allowed to enter the chamber. Once the liquid has drained from the chamber, the chamber is isolated from the siphon system, and the liquid filling stage is repeated. Continual cycling of this process can purge the siphon system of gases, or be used to produce a vacuum for other purposes.

The invention relates to circulation of fluids to an elevated container in general and more specifically a system and a method for circulation of fluids in a non-resistive manner to an elevated container with at least one fluid source container, at least one closed container for circulation, at least one elevated fluid container, at least one circulation mechanism for the purpose of circulation, and at least one start-stop mechanism for the purpose of circulation control.