초록 ▼

A system capable of converting fluid energy into electrical energy in conditions of low fluid flow is provided. In an embodiment, the system may engage and disengage an energy converter via an automatic clutch. In an embodiment, the transmission of energy to an energy converter is controlled by swit

A system capable of converting fluid energy into electrical energy in conditions of low fluid flow is provided. In an embodiment, the system may engage and disengage an energy converter via an automatic clutch. In an embodiment, the transmission of energy to an energy converter is controlled by switching the energy converter on and off. In another embodiment, the flow of electrical energy to an electrical load is controlled by a switching device. In another embodiment, a funnel is used for condensing the flow of fluid moving through the system.

대표청구항 ▼

The invention claimed is: 1. A system comprising: a turbine for converting energy of a flowing medium into electrical energy; a load; the load having at least two states, in a first of the at least two states the load is engaged with the turbine, slowing the speed at which the turbine spins, and in

The invention claimed is: 1. A system comprising: a turbine for converting energy of a flowing medium into electrical energy; a load; the load having at least two states, in a first of the at least two states the load is engaged with the turbine, slowing the speed at which the turbine spins, and in a second of the at least two states the load is disengaged from the turbine, the load being configured such that the load engages the turbine at a first threshold value, which is a turbine speed that is high enough to generate energy for duration of time after the load engages, while the turbine slows down as a result of the load engaging, but that is not high enough for the turbine to continue to generate energy with the load engaged, and the load disengages from the turbine when the speed of the turbine is below a second threshold value, the second threshold value being less than the first threshold value; a controller that periodically engages and disengages the load from a turbine at fixed intervals of time, while the fluid flows at a fixed speed; the time interval being dependent on a fluid speed of the fluid. 2. The system of claim 1, the load includes a generator, and engaging the load engages the generator, the generator does not draw power to act as a motor while engaged with the turbine. 3. The system of claim 1 the load includes a mass, engaging the load engages the mass altering the moment of inertia of the turbine, such that the turbine spins slower. 4. The system of claim 1 the load including at least an electrical load. 5. The system of claim 1, the load including at least a mechanical load, the system further comprising a clutch that engages the load to the turbine as a result of centrifugal force pulling arms of the clutch outwards during the first state. 6. The system of claim 5, load also includes at least an electrical load further comprising: a switch that is configured to electrically engage the electrical load while the turbine is spinning at a speed above a third threshold value as a result of the switch being in a first state, the switch causes the electrical load to disengage from the turbine when the speed of the turbine is below a fourth threshold value, as result of the switch being in a second state, the first state being different form the second state, and the third threshold value being higher than the fourth threshold value. 7. The system of claim 5, the arms being located on a first shaft each having a portion that engages a second shaft, one of the first and second shaft is associated with the turbine and the other of the first and second shaft is associated with the load, such that when the arms engage the second shaft the load is engaged to the turbine and when the arms disengage the second shaft the arms disengage from the turbine; the portion each of the arms that engages the second shaft are stationary with respect to the arms to which the portions are attached. 8. The system of claim 1, further comprising: a speed sensor for determining the speed at which the turbine rotates; and a clutch, the speed sensor sending a signal to the clutch causing the clutch to place the load in one of the at least two states. 9. The system of claim 1, further comprising a funnel, the turbine being located within the funnel, the funnel having an opening at one end of the funnel that is wider than other sections of the funnel, the funnel directing fluid towards the turbine, such that as the fluid travels towards the turbine within the funnel, the fluid travels towards a portion of the funnel that is narrower than the opening, the funnel being oriented about an axis that is parallel to an axis of the turbine, the funnel having a preferred direction for catching fluid, the preferred direction being parallel to the axis, such that a greater amount of fluid is caught by the funnel when the fluid travels in the preferred direction than when the fluid travels in another direction, fluid traveling in the preferred direction that is caught by the funnel tends to travel through the funnel in the preferred direction through the turbine and tends to power the turbine. 10. The system of claim 1, the turbine having blades that are constructed from a rigid material. 11. The system of claim 10, the electrical load engaging the turbine by at least the electrical load engaging a generator that is engaged with the turbine. 12. A system comprising: a turbine for converting energy of a flowing medium into electrical energy; a load; and a mechanism that is configured to engage the load while the turbine is spinning, the load has at least two states, in a first of the at least two states the load is engaged with the turbine, slowing the speed at which the turbine spins, and then in a second of the at least two states the load is disengaged from the turbine, the mechanism causes the load to disengage from the turbine when the speed of the turbine is below a threshold value; the load includes a generator, and engaging the load engages the generator; the turbine including at least blades mounted on a first shaft that rotates, such that as a fluid flows passed that blades of the turbine, the fluid causes the blades to rotate; and as the blades rotate, the first shaft rotates with the blades, the generator including at least a stator having a stationary magnet that generates a magnetic field a second shaft, a rotator connected to the second shaft, the rotator includes at least coils of electrical wire, as the second shaft rotates, the rotator rotates, which generates an electric current in the coils; and the mechanism including at least a clutch for engaging the first shaft, which is connected to the turbine, to the second shaft, which is connected to the generator; the system further comprising: a speed sensor for sensing the speed at which blades of the turbine rotate, signals from the speed indicating a speed at which the turbine rotates; and a controller for causing the clutch to engage and disengage, based on the signals from speed sensor, which are received by the controller, the controller causing the clutch to engage the first shaft to the second shaft when the turbine spins at a speed above a first threshold speed, and the clutch to disengage when the turbine spins at a speed that is below a second threshold speed that is below the first threshold speed; and the controller also periodically engages and disengages the load from a turbine at fixed intervals of time, while the fluid flows at a fixed speed; the time interval being dependent on a fluid speed of the fluid. 13. The system of claim 12 the load includes a mass, engaging the load engages the mass altering the moment of inertia of the turbine, such that the turbine spins slower. 14. The system of claim 12, further comprising: an electrical load; a switch communicatively coupled to the load for electrically connecting and disconnecting the load to the generator, based on the signals from the speed sensor, which are received by the switch, the switch causing the electrical load to be electrically connected to the generator when the turbine spins at a speed above a third threshold speed, and the load to be electrically disconnected from the generator when the turbine spins at a speed below a fourth threshold speed that is lower than the third threshold. 15. A system comprising: a turbine for converting energy of a flowing medium into electrical energy; a load; and a mechanism that is configured to engage the load while the turbine is spinning, the load has at least two states, in a first of the at least two states the load is engaged with the turbine, slowing the speed at which the turbine spins, and then in a second of the at least two states the load is disengaged from the turbine, the mechanism causes the load to disengage from the turbine when the speed of the turbine is below a threshold value; the load including at least an electrical load; the turbine including at least blades attached to a shaft, such that as a fluid flows passed the blades of the turbine, the blades rotate causing the shaft to rotate with the blades; the system further comprising a generator including at least a stator having a stationary magnet that generates a magnetic field a rotator coupled to the shaft, the rotator includes at least coils of electrical wire, as the shaft rotates, the rotator rotates, which generates an electric current in the coils; and a speed sensor for sensing the speed at which blades of the turbine rotate, signals from the speed indicating a speed at which the turbine rotates; and a switch communicatively coupled to the load for electrically connecting and disconnecting the load to the generator, based on the signals from the speed sensor, which are received by the switch, the switch causing the load to be electrically connected to the generator when the turbine spins at a speed above a first threshold speed, and the load to be electrically disconnected from the generator when the turbine spins at a speed below a second threshold speed that is lower than the first threshold speed. 16. The system of claim 15, further comprising a mass that engages the shaft altering the moment of inertia of the turbine, such that the turbine spins slower. 17. A method comprising: allowing a fluid to turn a turbine; periodically engaging and disengaging a load from the turbine at intervals of time; the time intervals being dependent on a fluid speed of the fluid, such that for a constant fluid speed the time intervals are equal to one another. 18. The method of claim 17, further comprising: determining that the fluid speed is sufficient to drive the turbine while the load is disengaged, and the fluid speed is insufficient to keep the turbine turning while the load is engaged; and in response to the determining performing the periodically engaging and disengaging. 19. The method of claim 17, the periodically engaging and disengaging being performed by at least engaging the load when the turbine speed is above a first threshold; and disengaging the load when the turbine speed is below a second threshold that is lower than the first threshold. 20. The method of claim 17, the turbine having at least blades that rotate in response to a fluid passing by the blades, and a shaft that is connected to, and rotates with, the blades; the engaging includes at least moving a mass from a first position to a second position in which the mass is engaged with a portion of a shaft so that the mass rotates with the shaft; and the disengaging includes at least moving the mass from the second position to the first position so that the mass does not rotate with the shaft.