초록 ▼

Sensor and/or power-harvesting apparatus are provided for sensing and/or harvesting energy across a relatively wide dynamic range of a driving rotational input. The apparatus may include a rotor magnet (10, 62) responsive to a driving rotational input (14, 64). Utilization of a togging effect or a m

Sensor and/or power-harvesting apparatus are provided for sensing and/or harvesting energy across a relatively wide dynamic range of a driving rotational input. The apparatus may include a rotor magnet (10, 62) responsive to a driving rotational input (14, 64). Utilization of a togging effect or a magnetic spring effect results in certain rapid-rotation events where the rotor magnet can rapidly rotate regardless of a low rate of rotation of the driving rotational input. A coil assembly (28, 75) is magnetically coupled to the rotor magnet to generate a signal in response to rotation of the rotor magnet during the rapid-rotation events. This signal may be used to harvest electrical energy and/or may be processed to determine characteristics of the driving rotational input.

대표청구항 ▼

1. A sensor apparatus comprising: a rotor assembly comprising a rotor magnet responsive to a driving rotational input;a pole-piece assembly magnetically coupled to the rotor magnet and having a pole-piece configured to effect a respective detent torque in at least two detent locations, wherein, as t

1. A sensor apparatus comprising: a rotor assembly comprising a rotor magnet responsive to a driving rotational input;a pole-piece assembly magnetically coupled to the rotor magnet and having a pole-piece configured to effect a respective detent torque in at least two detent locations, wherein, as the driving rotational input rotates beyond a threshold angle said detent torque is overcome, which causes the rotor magnet to angularly accelerate towards the other one of said at least two detent locations irrespective of a relatively low rate of rotation of the driving rotational input;a coil assembly magnetically coupled to the rotor magnet and the pole-piece assembly to generate a signal in response to rotation of the rotor magnet between said at least two detent locations; anda processor responsive to the signal from the coil assembly to determine data indicative of at least one characteristic of the rotational input. 2. The sensor apparatus of claim 1, wherein the driving rotational input is effected by a fluid flow and said at least one characteristic of the rotational input comprises one or more of the following: a flow rate of the fluid flow, a quantity of flow over a period of time and a direction of the flow. 3. The sensor apparatus of claim 1, wherein the driving rotational input is effected by a rotating structure and said at least one characteristic of the rotational input comprises one or more of the following: a rotation rate of the structure, a number of rotations over a period of time and a direction of rotation of the structure. 4. The sensor apparatus of claim 1, further comprising a drive magnet to magnetically convey the driving rotational input to the rotor magnet. 5. The sensor apparatus of claim 1, wherein the signal generated by the coil assembly comprises a stream of pulses. 6. The sensor apparatus of claim 5, further comprising at least one circuit component arranged to accumulate electrical energy from the stream of pulses generated by the coil assembly. 7. The sensor apparatus of claim 1, further comprising a non-volatile memory to store the data from the processor. 8. The sensor apparatus of claim 1, wherein the respective detent torque is effected in said at least two detent locations by way of magnetic coupling. 9. The sensor apparatus of claim 1, wherein the respective detent torque is effected in said at least two detent locations by way of mechanical coupling. 10. The sensor apparatus of claim 1, wherein the respective detent torque is effected in said at least two detent locations by way of magnetic coupling and/or mechanical coupling. 11. A flow meter register comprising the sensor apparatus of claim 1. 12. A power-harvesting apparatus comprising: a rotor assembly comprising a rotor magnet responsive to a driving rotational input;a pole-piece assembly magnetically coupled to the rotor magnet and having a pole-piece configured to effect a respective detent torque in at least two detent locations, wherein, as the driving rotational input rotates beyond a threshold angle said detent torque is overcome, which causes the rotor magnet to angularly accelerate towards the other one of said at least two detent locations irrespective of a relatively low rate of rotation of the driving rotational input;a coil assembly magnetically coupled to the rotor magnet and the pole-piece assembly to generate a signal comprising a stream of pulses in response to rotation of the rotor magnet; andat least one circuit component connected to the coil assembly to receive the stream of pulses generated by the coil assembly and accumulate electrical energy extracted from the received stream of pulses. 13. The power-harvesting apparatus of claim 12, wherein the driving rotational input is effected by a fluid flow. 14. The power-harvesting apparatus of claim 12, wherein the driving rotational input is effected by a rotating structure. 15. The power-harvesting apparatus of claim 12, further comprising a drive magnet to magnetically convey the driving rotational input to the rotor magnet. 16. The power-harvesting apparatus of claim 12, wherein the respective detent torque is effected in said at least two detent locations by way of magnetic coupling. 17. The power-harvesting apparatus of claim 12, wherein the respective detent torque is effected in said at least two detent locations by way of mechanical coupling. 18. The power-harvesting apparatus of claim 12, wherein the respective detent torque is effected in said at least two detent locations by way of magnetic coupling and/or mechanical coupling. 19. A flow meter register comprising the power-harvesting apparatus of claim 12. 20. Apparatus for sensing and power-harvesting comprising: a rotor assembly comprising a rotor magnet responsive to a driving rotational input;a pole-piece assembly magnetically coupled to the rotor magnet and having a pole-piece configured to effect a respective detent torque in at least two detent locations, wherein, as the driving rotational input rotates beyond a threshold angle said detent torque is overcome, which causes the rotor magnet to angularly accelerate towards the other one of said at least two detent locations irrespective of a relatively low rate of rotation of the driving rotational input;a coil assembly magnetically coupled to the rotor magnet and the pole-piece assembly to generate a signal comprising a stream of pulses in response to rotation of the rotor magnet;a processor to determine data indicative of at least one characteristic of the rotational input;a wakeup switching circuit responsive to the stream of pulses to awake the processor from a power saving condition to determine said at least one characteristic of the rotational input based on the stream of pulses from the coil assembly; andat least one circuit component connected to the coil assembly to further receive the stream of pulses generated by the coil assembly and accumulate electrical energy extracted from the received stream of pulses. 21. A sensor apparatus comprising: a drive magnet arranged to produce a rotating magnetic field in response to a driving rotational input;a rotor assembly comprising a rotor magnet responsive to the rotating magnetic field from the drive magnet, wherein the rotor assembly includes a mechanical stop to impede further rotation of the rotor magnet beyond a predefined location of the rotor assembly as the rotating magnetic field continues to rotate, wherein a magnetic spring effect is established between the stopped rotor magnet and the rotating magnetic field, which eventually causes the rotor magnet to angularly accelerate and rotate away from the mechanical stop irrespective of a relatively low rate of rotation of the driving rotational input;a coil assembly magnetically coupled to the rotor magnet to generate a signal in response to the rotation of the rotor magnet away from the mechanical stop; anda processor responsive to the signal from the coil assembly to determine data indicative of at least one characteristic of the rotational input. 22. The sensor apparatus of claim 21, wherein the driving rotational input is effected by a fluid flow and said at least one characteristic of the rotational input comprises one or more of the following: a flow rate of the fluid flow, a quantity of flow over a period of time and a direction of the flow. 23. The sensor apparatus of claim 21, wherein the driving rotational input is effected by a rotating structure and said at least one characteristic of the rotational input comprises one or more of the following: a rotation rate of the structure, a number of rotations over a period of time and a direction of rotation of the structure. 24. The sensor apparatus of claim 21, wherein the signal generated by the coil assembly comprises a stream of pulses. 25. The sensor apparatus of claim 24, further comprising at least one circuit component connected to the coil assembly to receive the stream of pulses generated by the coil assembly and accumulate electrical energy extracted from the received stream of pulses. 26. The sensor apparatus of claim 21, further comprising a non-volatile memory to store the data from the processor. 27. A flow meter register comprising the sensor apparatus of claim 21.