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Systems and methods for modifying ice adhesion strength of ice adhered to an object. An electrode is electrically insulated from the object and a power source, e.g., a battery, is coupled to the object and the electrode. The source generates power to an interface between the ice and the object when

Systems and methods for modifying ice adhesion strength of ice adhered to an object. An electrode is electrically insulated from the object and a power source, e.g., a battery, is coupled to the object and the electrode. The source generates power to an interface between the ice and the object when the ice completes the circuit. The object is conductive or is doped as a semiconductor so that a voltage to the interface selectively modifies the ice adhesion strength. The strength can be increased or decreased relative to its static state (i.e., the state without applied voltage). Ice can, thus, be removed with less work. The system preferably includes an electrically insulating material disposed between the object and the electrode; the insulating material is substantially conformal to the object and the electrode. The invention also includes a ferroelectric material applied to power lines to melt or prevent ice formation.

대표청구항 ▼

1. In a power line of the type that provides power to different locales and is suspended above ground, the improvement to reduce or prevent ice, comprising a coating covering the surface of the power line, which coating, when subjected to an approximately radially directed AC field associated with a

1. In a power line of the type that provides power to different locales and is suspended above ground, the improvement to reduce or prevent ice, comprising a coating covering the surface of the power line, which coating, when subjected to an approximately radially directed AC field associated with an AC voltage on the power line, dissipates sufficient power through dielectric loss to generate sufficient heat to melt ice or prevent its formation, the AC voltage being not less than about 10 kV. 2. In a power line of claim 1, the further improvement wherein the coating has a thickness selected to correspond to a desired rate of heat generation by the coating. 3. In a power line of claim 1, the further improvement wherein the coating comprises a semiconductor material. 4. In a power line of claim 1, the further improvement wherein the heat generated from dissipated power of the dielectric loss changes as a function of ambient temperature. 5. In a power line of claim 1, the further improvement wherein the coating has a thickness in a range of about 0.2 mm to 1 mm. 6. In a power line of the type that provides power to different locales and is suspended above ground, the improvement to reduce or prevent ice, comprising a coating covering the surface of the power line, which coating, when subjected to an approximately radially directed AC field associated with an AC voltage on the power line, dissipates sufficient power through dielectric loss to generate sufficient heat to melt ice or prevent its formation, and an AC power source for providing AC power having a frequency in a range of about 15 Hz to 1000 Hz. 7. A method of reducing or preventing ice on a power line of the type that provides power to different locales and is suspended above ground, comprising steps of:covering the power line with a coating, which, when subjected to an approximately radially directed AC field associated with an AC voltage on the power line, dissipates sufficient power through dielectric loss to generate sufficient heat to melt ice or prevent its formation; andapplying AC power to the power line, in a frequency range of about 15 Hz to 1000 Hz, to generate the AC field in the coating. 8. A method as in claim 7, wherein the step of covering the power line comprises selecting a coating thickness to correspond to a desired dielectric loss heat. 9. A method as in claim 8, wherein the desired dielectric loss heat changes as a function of ambient temperature. 10. A method as in claim 7, wherein the step of covering comprises covering the power line with a semiconductor material. 11. A method of reducing or preventing ice on a power line of the type that provides power to different locales and is suspended above ground, comprising steps of:covering the power line with a coating, which, when subjected to an approximately radially directed AC field associated with an AC voltage on the power line, dissipates sufficient power through dielectric loss to generate sufficient heat to melt ice or prevent its formation; andapplying AC power to the power line, with a voltage of not less than 10 kV, to generate the AC field in the coating. 12. A power line, comprising:a power source configured for supplying power having a frequency in a range of about 15 Hz to 1000 Hz; anda power line coating connected to the power source for receiving the power of the power source to substantially dissipate ice from the power line. 13. The power line of claim 12, the power line coating comprising a dielectric for controllably absorbing the power and converting the power to heat through dielectric losses. 14. The power line of claim 12, further comprising AC power distributed through the power line. 15. The power line of claim 12, further comprising AC power externally distributed from the power line. 16. A power line, comprising:a power source configured for supplying power; anda power line coating, connected to the power source for receiving the power of the power source to substantiall y dissipate ice from the power line, comprising a dielectric for controllably absorbing the power and converting the power to heat through dielectric losses, wherein the dielectric having permittivity in a range of approximately 3 to 5 relative to a frequency of the power before ice forms on the power line. 17. A power line, comprising:a power source configured for supplying power; anda power line coating, connected to the power source for receiving the power of the power source to substantially dissipate ice from the power line, comprising:an insulator connected to the power line; andconductive elements connected to the insulator for substantially dissipating the ice as the ice electrically couples the conductive elements to the power source. 18. The power line of claim 17, the power line coating comprising a dielectric for controllably absorbing the power and converting the power to heat through dielectric losses. 19. The power line of claim 18, the dielectric comprising a permittivity having a range of approximately 3 to 5 relative to a frequency of the power before ice forms on the power line.