A wireless (e.g., radio) system and method for automatic water level maintenance of, e.g., a swimming pool utilizing capacitive liquid level sensing. A reference electrode allows water level sensing independent of the water chemistry or temperature. Capacitive electrodes having areas larger than the
A wireless (e.g., radio) system and method for automatic water level maintenance of, e.g., a swimming pool utilizing capacitive liquid level sensing. A reference electrode allows water level sensing independent of the water chemistry or temperature. Capacitive electrodes having areas larger than the reference electrode sense various liquid levels when the liquid covers an area of any sensing electrode equal to the area of the reference electrode. Averaging is incorporated to filter out effects of wind or other disturbances. Upon sensing a given condition, the transmitter transmits a sensed condition to a remote receiver for control of valves and pumps for changing the water level in the pool. The receiver includes safety timers for filling and emptying to protect against equipment failure or communications faults. User selectable identification allows identical such radio systems to operate within proximity to each other. Power saving features are used to extend battery life.
대표청구항▼
I claim: 1. A capacitive sensor for determining liquid level, comprising: a surface adjacent which the liquid is present, and on which the fluid defines a level; a single reference electrode at a lower part of the surface; a first sensor electrode arranged at least in part above the reference elect
I claim: 1. A capacitive sensor for determining liquid level, comprising: a surface adjacent which the liquid is present, and on which the fluid defines a level; a single reference electrode at a lower part of the surface; a first sensor electrode arranged at least in part above the reference electrode at the surface; and a second sensor electrode arranged at least in part above the first sensor electrode and at the surface; wherein each of the first and second sensor electrode has a greater area at the surface than does the reference electrode; and wherein the surface is defined by one or more passages through the sensor and the electrodes are each concentric to one of the passages. 2. The sensor of claim 1, wherein the surface is defined by two passages in the sensor, the reference electrode and the second sensor electrode being concentric to a first of the passages and the first sensor electrode being concentric to a second of the passages, the second sensor electrode extending from below a top of the first sensor electrode. 3. The sensor of claim 1, wherein the surface is defined by a single passage defined through the sensor and the electrode are each concentric to the single passage. 4. The sensor of claim 2, further comprising a third sensor electrode concentric to the second of the passages and extending from below a top of the second sensor electrode to above the top of the second sensor electrode. 5. The sensor of claim 4, wherein the first, second, and third sensor electrodes are respectively arranged to determine that the level of the liquid relative to a nominal level is below the nominal level, at the nominal level, or above the nominal level. 6. The sensor of claim 2, further comprising a common electrode located in each of the two passages below respectively the reference and first electrodes. 7. The sensor of claim 1, further comprising a wireless transmitter coupled to the electrodes, thereby to transmit the determined fluid level to a remote receiver. 8. The sensor of claim 7, in combination with the receiver, wherein the receiver includes at least one driver adapted to actuate a valve. 9. The sensor of claim 1, wherein the reference, first and second electrodes are arranged on a single surface of the sensor and further comprising a third sensor electrode arranged on the single surface, wherein the second sensor electrode extends from below a top of the first sensor electrode to above the top of the first sensor electrode, and the third sensor electrode extends from below a top of the second sensor electrode to above the top of the second sensor electrode. 10. The sensor of claim 1, wherein each of the electrodes is a plate of a capacitive circuit element, and further comprising a voltage sensing circuit coupled to each of the electrodes, and a flip flop coupled to each of the first and second sensor electrodes and being clocked by the reference electrode. 11. The sensor of claim 1, wherein the electrodes are covered by an insulate layer on the surface. 12. The sensor of claim 1, wherein at least one of the electrodes defines an arc around a common axis of two of the electrodes. 13. The sensor of claim 1, further comprising: measuring logic coupled to the electrodes; and a wireless transmitter coupled to the measuring logic. 14. The sensor of claim 1, further comprising: measuring logic coupled to the electrodes; and a microcontroller comprising a sleep mode and code to average a series measurements; and wherein the microcontroller is coupled to the measuring logic. 15. A capacitive liquid level sensor comprising: a reference electrode defining a surface area and positioned over a surface; a first electrode defining a surface area and positioned over the surface, wherein the surface area of the first electrode is greater than the surface area of the reference electrode, and wherein a geometric center of the surface area of the first electrode is positioned above a geometric center of the surface area of the reference electrode; a second electrode defining a surface area and positioned over the surface, wherein the surface area of the second electrode is greater than the surface area of the reference electrode, and wherein a geometric center of the surface area of the second electrode is positioned above the geometric center of the surface area of the first electrode; and measuring logic to measure a representation of a capacitance at the first electrode relative to a capacitance at the reference electrode and to measure a representation of a capacitance at the second electrode relative to a capacitance at the reference electrode. 16. The capacitive liquid level sensor of claim 15, wherein the surface defines a plane. 17. The capacitive liquid level sensor of claim 15, wherein the surface defines a passage. 18. The capacitive liquid level sensor of claim 15, further comprising: a third electrode defining a surface area and positioned over the surface, wherein the surface area of the third electrode is greater than the surface area of the reference electrode, and wherein a geometric center of the surface area of the third electrode is positioned above the geometric center of the surface area of the second electrode; and wherein the measuring logic is further to measure a representation of a capacitance at the third electrode relative to a capacitance at the reference electrode. 19. The capacitive liquid level sensor of claim 15, further comprising a wireless transmitter coupled to the measuring logic. 20. The capacitive liquid level sensor of claim 15, further comprising: a microcontroller comprising a sleep mode and code to average a series measurements; and wherein the microcontroller is coupled to the measuring logic. 21. A method of controlling a liquid level in a reservoir, the method comprising: measuring a representation of a capacitance at a first electrode relative to a capacitance at a reference electrode; measuring a representation of a capacitance at a second electrode relative to a capacitance at the reference electrode; determining the liquid level has decreases to a first predetermined level based on the representation of the capacitance at the first electrode; sending a signal to start filling the reservoir in response to determining the liquid level has decreases to the first predetermined level; determining the liquid level has increases from the first predetermined level to a second predetermined level based on the representation of the capacitance at the second electrode; and sending a signal to stop filling the reservoir in response to determining the liquid level has increases from the first predetermined level to the second predetermined level. 22. The method of claim 21, further comprising: measuring a representation of a capacitance at a third electrode relative to a capacitance at a reference electrode; determining the liquid level has increased to a third predetermined level based on the representation of the capacitance at the third electrode; sending a signal to start draining the reservoir in response to determining the liquid level has increases to the third predetermined level; determining the liquid level has decreased from the third predetermined level to the second predetermined level based on the representation of the capacitance at the second electrode; and sending a signal to stop draining the reservoir in response to determining the liquid level has decreases from the third predetermined level to the second predetermined level. 23. The method of claim 21, wherein measuring the representations of the capacitances comprises averaging a sequence of values. 24. The method of claim 21, further comprising deactivating a sleep mode with a magnet.
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