초록 ▼

A power control interface between an unstable power source such as a wind farm and a power transmission line employs an electrical energy storage, control system, and electronic compensation module which act together like an "electronic shock absorber" for storing excess power during periods of incr

A power control interface between an unstable power source such as a wind farm and a power transmission line employs an electrical energy storage, control system, and electronic compensation module which act together like an "electronic shock absorber" for storing excess power during periods of increased power generation and releasing stored energy during periods of decreased power generation due to wind fluctuations. The control system is provided with a "look ahead" capability for predicting power output (wind speed conditions) and maintaining energy storage or release over a "narrow-band" range despite short duration fluctuations. The control system uses data derived from monitoring the wind farm power output and the power transmission line, and employs system-modeling algorithms to predict narrow-band wind speed conditions. The power control interface can also use its energy storage capacity to provide voltage support at the point of injection into the power transmission system, as well as fault clearance capability for "riding out" transient fault conditions occurring on the power transmission line.

대표청구항 ▼

The invention claimed is: 1. A power control interface between a power output of an unstable power source such as a wind farm having an expected normal output level of power output during average operating conditions and a power transmission line, comprising: (a) an electrical energy storage couple

The invention claimed is: 1. A power control interface between a power output of an unstable power source such as a wind farm having an expected normal output level of power output during average operating conditions and a power transmission line, comprising: (a) an electrical energy storage coupled between the unstable power source and the power transmission line to store its excess power output when it is above a normal output level of the unstable power source and to release stored electrical energy to add to its power output when it is below the normal output level of the unstable power source; (b) a control system which includes a unstable power source monitoring means, a transmission line monitoring means, and a control means including an electronic compensation module coupled to the electrical energy storage for operating the electrical energy storage to store excess power output as stored electrical energy and to release stored electrical energy as added power output in accordance with signals from said unstable power source monitoring means and said transmission line monitoring means, wherein said electrical energy storage is configured to have a relatively small storage capacity sufficient to accommodate power fluctuations typically expected to be encountered in a narrow band range of fluctuations of the unstable power source; and (c) said electronic compensation module being operated in response to a narrow band range of fluctuations of the unstable power source so as to release electrical energy stored in the electrical energy storage to add to the power output to the power transmission line when the power output of the unstable power source is below its normal output level, and to store excess power output from the unstable power source in the electrical energy storage when the power output of the unstable power source is above its normal output level, whereby operation of the electronic compensation module in the narrow-band range of fluctuations enables use of electrical energy storage with a relatively small storage capacity to reduce energy storage costs. 2. A power control interface according to claim 1, wherein the power source is a wind farm providing an AC power output, and the power output is stored in a selected one of the group of electrical energy storage devices consisting of ultracapacitors, capacitors, and batteries. 3. A power control interface according to claim 1, wherein the power source is a wind farm providing an AC power output, and the AC power output is converted by an ac-to-dc inverter to direct current (DC) for storage in a DC capacitor array or battery. 4. A power control interface according to claim 1, wherein the electronic compensation module is operated by calculating what the power output of the unstable power source is likely to be over a narrow-band range of fluctuations and maintaining the release of electrical energy over the calculated narrow-band range. 5. A power control interface according to claim 1, wherein the power source is a wind farm, and the control system receives data signals derived from monitoring the power output of the wind farm, and data signals derived from monitoring conditions on the transmission line, and employs system-modeling algorithms to predict narrow-band wind fluctuation conditions based on said data signals. 6. A power control interface according to claim 5, wherein the control system's algorithms include prediction based on current data on wind farm output and historical data of wind farm output. 7. A power control interface according to claim 1, wherein the electrical energy storage includes an energy storage circuit, a charge controller at an input side of the energy storage circuit, and a discharge controller at an output side of the energy storage circuit for energy release. 8. A power control interface according to claim 7, wherein the charge controller and the discharge controller act like double-action gates controlled by signals from the electronic compensation module. 9. A power control interface according to claim 7, wherein the power source is a wind farm providing an AC power output, and the power output is stored in a selected one of the group of electrical energy storage devices consisting of ultracapacitors, capacitors, and batteries. 10. A power control interface according to claim 9, wherein the electrical energy storage is an array of ultracapacitors arranged to store electrical energy in respective stages. 11. A power control interface according to claim 1, further comprising power electronics circuitry for providing voltage support at the point of connection of the wind farm with the power transmission line for adjusting to power disturbances on the transmission line. 12. A power control interface according to claim 1, wherein the electrical storage capacity is sized to be about 1.5 times the typical expected maximum power excursion for the unstable power source. 13. A power control method for interfacing between a power output of an unstable power source such as a wind farm having an expected normal output level of power output during average operating conditions and a power transmission line, comprising: (a) providing an electrical energy storage coupled between the unstable power source and the power transmission line to store its excess power output when it is above a normal output level of the unstable power source and to release stored electrical energy to add to its power output when it is below the normal output level of the unstable power source; (b) providing a control system which includes a unstable power source monitoring means, a transmission line monitoring means, and a control means including an electronic compensation module coupled to the electrical energy storage for operating the electrical energy storage to store excess power output as stored electrical energy and to release stored electrical energy as added power output in accordance with signals from said unstable power source monitoring means and said transmission line monitoring means, wherein said electrical energy storage is configured to have a relatively small storage capacity sufficient to accommodate power fluctuations typically expected to be encountered in a narrow band range of fluctuations of the unstable power source; and (c) operating said electronic compensation module in response to a narrow band range of fluctuations of the unstable power source so as to release electrical energy stored in the electrical energy storage to add to the power output to the power transmission line when the power output of the unstable power source is below its normal output level, and to store excess power output from the unstable power source in the electrical energy storage when the power output of the unstable power source is above its normal output level, whereby operation of the electronic compensation module in the narrow-band range of fluctuations enables use of electrical energy storage with a relatively small storage capacity to reduce energy storage costs. 14. A power control method according to claim 13, further comprising calculating what the power output of the unstable power source is likely to be over a narrow-band range of fluctuations and maintaining the release of electrical energy or the storage of electrical energy in the electrical energy storage over the calculated narrow-band range. 15. A power control method according to claim 13, wherein the power source is a wind farm, and the control system receives data signals derived from monitoring the power output of the wind farm, and data signals derived from monitoring conditions on the transmission line, and employs system-modeling algorithms to predict narrow-band wind fluctuation conditions based on said data signals. 16. A power control method according to claim 15, wherein the control system's algorithms include prediction based on current data on wind farm output and historical data of wind farm output. 17. A power control method according to claim 13, wherein the electrical energy storage includes an energy storage circuit, a charge controller at an input side of the energy storage circuit, and a discharge controller at an output side of the energy storage circuit for energy release. 18. A power control method according to claim 17, wherein the charge controller and the discharge controller act like double-action gates controlled by signals from the electronic compensation module. 19. A power control method according to claim 13, further comprising providing voltage support at the point of connection of the wind farm with the power transmission line for adjusting to power disturbances on the transmission line. 20. A power control method according to claim 13, wherein the electrical storage capacity is sized to be about 1.5 times the typical expected maximum power excursion for the unstable power source.