초록 ▼

Disclosed are a method, a device and a system of automatic flow control based on sensed effectiveness indicators to produce effectively treated water with a portable water treatment unit. In one or more embodiments, a chemical treatment unit delivers a treatment chemical to water as the water flows

Disclosed are a method, a device and a system of automatic flow control based on sensed effectiveness indicators to produce effectively treated water with a portable water treatment unit. In one or more embodiments, a chemical treatment unit delivers a treatment chemical to water as the water flows at a flow rate induced by a pump capable of operating at multiple speeds. A sensor downstream of the chemical treatment unit measures an effectiveness indicator and a processor and/or a feedback circuit determines an effectiveness of the chemical treatment. A controller changes power to the pump in response to the determination, adjusting the flow rate to ensure efficient usage of a power source and/or to ensure effective production of potable water. One or more filters may be included, each having a bypass valve, and the pump may automatically adjust to changing filter configurations and/or source water composition.

대표청구항 ▼

1. A portable water treatment system comprising: a pump connected to a tubing and capable of operating at multiple speeds to draw water at multiple flow rates through a source end of the tubing to a product end of the tubing;a chemical treatment unit connected to an interstitial section of the tubin

1. A portable water treatment system comprising: a pump connected to a tubing and capable of operating at multiple speeds to draw water at multiple flow rates through a source end of the tubing to a product end of the tubing;a chemical treatment unit connected to an interstitial section of the tubing, the chemical treatment unit comprising a chemical applicator to deliver a treatment chemical to the water as the water flows through the tubing and past the chemical treatment unit at a flow rate induced by the pump;a sensor connected to the tubing and located at least one of at the chemical treatment unit and downstream of the chemical treatment unit to measure an effectiveness value of an effectiveness indicator of the chemical treatment, wherein the effectiveness indicator comprises at least one of a concentration of the chemical treatment, an oxidation-reduction potential, a pH, and an operational metric of the chemical treatment unit;at least one of a processor and a feedback circuit communicatively coupled to the sensor programmed to compare the effectiveness value of the effectiveness indicator to a reference value to determine an effectiveness of the chemical treatment added to the water by the portable water treatment system;a controller communicatively coupled to the at least one of the processor and the feedback circuit programmed to adjust the flow rate of the pump in response to the determination of the effectiveness of the chemical treatment in the water by the at least one of the processor and the feedback circuit; anda power source of the portable water treatment system connected to and providing power to at least one of, the pump, the processor, the feedback circuit, the chemical treatment unit, and the controller. 2. The system of claim 1, wherein the chemical treatment is ozone and the chemical treatment unit is an ozone generator that dissolves ozone in the water flow passing the ozone generator. 3. The system of claim 2, wherein the ozone generator is an electrolytic cell utilizing a diamond material in at least one of an anode and a cathode of the electrolytic cell. 4. The system of claim 1, wherein the sensor is integrated into the chemical treatment unit. 5. The system of claim 3, wherein the sensor comprises at least one of an ozone concentration sensor and an oxidation-reduction potential probe. 6. The system of claim 1, further comprising: An external housing enclosing the pump, the chemical treatment unit, the at least one of the processor and the feedback circuit, and the controller;one or more instances of a fine filter connected to the tubing upstream of the chemical treatment unit; andone or more bypass valves routing the water flow drawn through the tubing by the pump around at least one of the one or more instances of the fine filter. 7. The system of claim 1, further comprising: an oxidation chamber connected to the tubing and receiving ozone of the ozone generator through at least one of a venturi aided by the water flow and an atmosphere assist providing a positive air pressure to aid in dissolving ozone in the water, wherein the sensor located at least one of at the chemical treatment unit is located in the oxidation chamber. 8. A portable water treatment apparatus comprising: a pump connected to a tubing and capable of operating at multiple speeds to draw water at multiple flow rates through a source end of the tubing to a product end of the tubing;an electrolytic cell for generating ozone connected to an interstitial section of the tubing for delivering an ozone treatment to the water as the water flows through the tubing and past the electrolytic cell at a flow rate induced by the pump;a sensor connected to the tubing located at least one of at the electrolytic cell and downstream of the electrolytic cell to measure an effectiveness value of an effectiveness indicator of the ozone treatment, wherein the effectiveness indicator of the ozone treatment comprises at least one of an operational metric of the electrolytic cell, a current of the electrolytic cell, a voltage of the electrolytic cell, an ozone concentration, and an oxidation-reduction potential;a microcontroller comprising a processor and a memory, the microcontroller communicatively coupled to the sensor and the pump and programmed to: compare the effectiveness value of the effectiveness indicator to a reference value stored in the memory of the microcontroller to determine an effectiveness of the ozone treatment added to the water by the electrolytic cell, andadjust the flow rate of the pump in response to the determination of the effectiveness of the ozone treatment in the water by the comparison of the effectiveness value to the reference value; anda power source of the portable water treatment system connected to and providing power to at least one of the pump, the processor, the electrolytic cell, and the microcontroller. 9. The system of claim 8, wherein at least one of an anode of the electrolytic cell and a cathode of the electrolytic cell comprising a doped diamond material. 10. The system of claim 8, wherein the sensor is integrated into the electrolytic cell. 11. The system of claim 8, wherein the sensor comprising an ozone concentration sensor. 12. The system of claim 8, wherein the sensor comprising an oxidation-reduction potential probe. 13. The system of claim 8, further comprising: an external housing enclosing the pump, the chemical treatment unit, the at least one of the processor and the feedback circuit, and the controller;one or more instances of a fine filter connected to the tubing upstream of the electrolytic cell;one or more bypass valves routing the water flow drawn through the tubing by the pump around at least one of the one or more instances of the fine filter; andthe microcontroller communicatively coupled to the sensor and the pump further operable to: determine a current voltage of the power source, anddisable the pump when the current voltage of the power source is below a threshold voltage. 14. A portable water treatment apparatus comprising: a pump connected to a tubing and capable of operating at multiple speeds to draw water at multiple flow rates through a source end of the tubing to a product end of the tubing,an electrolytic cell for generating ozone connected to an interstitial section of the tubing for delivering an ozone treatment to the water as the water flows through the tubing and past the electrolytic cell at a flow rate induced by the pump,a sensor connected to the tubing located at least one of at the electrolytic cell and downstream of the electrolytic cell to measure an effectiveness value of an effectiveness indicator of the ozone treatment, wherein the effectiveness indicator of the ozone treatment comprises at least one of an operational metric of the electrolytic cell, a current of the electrolytic cell, a voltage of the electrolytic cell, an ozone concentration, and an oxidation-reduction potential,one or more instances of a fine filter connected to the tubing upstream of the electrolytic cell,one or more bypass valves routing the water flow drawn through the tubing by the pump around at least one of the one or more instances of the fine filter,a controller comprising a processor and a memory, the controller communicatively coupled with the sensor and the pump and the memory comprising computer-readable instructions that when executed on the processor cause the processor to adjust to deactivation of one or more bypass valves routing the water through the one or more instances of the fine filter by: comparing the effectiveness value of the effectiveness indicator to a reference value stored in the memory of the microcontroller to determine an effectiveness of the ozone treatment added to the water by the electrolytic cell, andadjusting the flow rate of the pump in response to the determination of the effectiveness of the ozone treatment in the water by the comparison of the effectiveness value to the reference value,a power source of the portable water treatment system connected to and providing power to at least one of the pump, the processor, the feedback circuit, the electrolytic cell, and the controller. 15. The system of claim 14, wherein the memory further comprising computer readable instructions that when executed on the processor causes the processor to: determine a current voltage of the power source, anddisable the pump when the current voltage of the power source is below a threshold voltage. 16. The system of claim 15, wherein the sensor comprising an ozone concentration sensor. 17. The system of claim 15, wherein the sensor comprising an oxidation-reduction potential probe.