IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0044388
(2011-03-09)
|
등록번호 |
US-8262029
(2012-09-11)
|
발명자
/ 주소 |
|
출원인 / 주소 |
- Star Technology and Research, Inc.
|
대리인 / 주소 |
Dicke, Billig & Czaja, PLLC
|
인용정보 |
피인용 횟수 :
1 인용 특허 :
9 |
초록
▼
An electrodynamic method includes providing an electrodynamic structure with a periphery, providing power, collecting electrons, and emitting electrons. The emitting electrons and the collecting electrons utilizes at least 20% of the periphery of the electrodynamic structure. The method includes con
An electrodynamic method includes providing an electrodynamic structure with a periphery, providing power, collecting electrons, and emitting electrons. The emitting electrons and the collecting electrons utilizes at least 20% of the periphery of the electrodynamic structure. The method includes conducting current to provide at least one of electrodynamic propulsion and power generation.
대표청구항
▼
1. An electrodynamic method comprising: providing an electrodynamic structure;providing power;collecting electrons with collectors;emitting electrons with emitters;providing a total length of conductors at least 20% larger than the perimeter of the largest planar projection area of the smallest sing
1. An electrodynamic method comprising: providing an electrodynamic structure;providing power;collecting electrons with collectors;emitting electrons with emitters;providing a total length of conductors at least 20% larger than the perimeter of the largest planar projection area of the smallest single shape without holes enclosing the collectors, the emitters, and the conductors; andconducting current through the conductors to provide at least one of electrodynamic propulsion and power generation;wherein the largest planar projection area of the smallest single shape without holes enclosing the collectors, the emitters, and the conductors is at least 25% of an area of a circle having a circle perimeter equal to the perimeter of the largest planar projection area. 2. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting current to provide the at least one of electrodynamic propulsion and power generation. 3. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting to control system dynamics through an interaction between electric currents and an ambient magnetic field. 4. The electrodynamic method of claim 1, comprising: controlling switches to direct current through the conductors and provide the at least one of electrodynamic propulsion and power generation. 5. The electrodynamic method of claim 1, comprising: changing direction of the conducting current to control the at least one of electrodynamic propulsion and power generation. 6. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting current to generate power from electro-motive force. 7. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting current to control solar energy collection rates. 8. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting current to produce a cumulative variation of orbital elements over a given period of time. 9. The electrodynamic method of claim 1, comprising: controlling collecting electrons, emitting electrons, and conducting current to change at least one of spin axis, spin phase, and rotation rate. 10. The electrodynamic method of claim 1, comprising: controlling switches to control closed loop currents and produce torque to thereby control an attitude of the electrodynamic structure. 11. The electrodynamic method of claim 1, comprising: controlling conducting current to control rotation rate of the electrodynamic structure to spin stabilize the electrodynamic structure. 12. The electrodynamic method of claim 1, wherein the electrodynamic structure has a periphery and the emitting electrons and the collecting electrons utilizes at least 20% of the periphery of the electrodynamic structure. 13. An electrodynamic method comprising: providing an electrodynamic structure with a periphery;providing power;collecting electrons with collectors;emitting electrons with emitters, wherein the emitting electrons and the collecting electrons utilizes at least 20% of the periphery of the electrodynamic structure; andconducting current through conductive paths to provide at least one of electrodynamic propulsion and power generation;wherein the largest planar projection area of the smallest single shape without holes enclosing the collectors, the emitters, and the conductive paths is at least 25% of an area of a circle having a circle perimeter equal to the perimeter of the largest planar projection area. 14. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting current to provide the at least one of electrodynamic propulsion and power generation. 15. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting to control system dynamics through an interaction between electric currents and an ambient magnetic field. 16. The electrodynamic method of claim 13, comprising: controlling switches in the conductive paths to direct current through the conductive paths and provide the at least one of electrodynamic propulsion and power generation. 17. The electrodynamic method of claim 13, comprising: changing direction of the conducting current to control the at least one of electrodynamic propulsion and power generation. 18. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting current to generate power from electro-motive force. 19. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting current to control solar energy collection rates. 20. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting current to produce a cumulative variation of orbital elements over a given period of time. 21. The electrodynamic method of claim 13, comprising: controlling collecting electrons, emitting electrons, and conducting current to change at least one of spin axis, spin phase, and rotation rate. 22. The electrodynamic method of claim 13, comprising: controlling switches in the conductive paths to control closed loop currents and produce torque to thereby control an attitude of the electrodynamic structure. 23. The electrodynamic method of claim 13, comprising: controlling conducting current to control rotation rate of the electrodynamic structure to spin stabilize the electrodynamic structure. 24. The electrodynamic method of claim 13, comprising: providing a total length of conductors at least 20% larger than the perimeter of the largest planar projection area of the smallest single shape without holes enclosing the collectors, the emitters, and the conductive paths.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.