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Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0246155 (2002-09-18) |
발명자 / 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 | 피인용 횟수 : 334 인용 특허 : 113 |
A ballast circuit is disclosed for inductively providing power to a load. The ballast circuit includes an oscillator, a driver, a switching circuit, a resonant tank circuit and a current sensing circuit. The current sensing circuit provides a current feedback signal to the oscillator that is represe
A ballast circuit is disclosed for inductively providing power to a load. The ballast circuit includes an oscillator, a driver, a switching circuit, a resonant tank circuit and a current sensing circuit. The current sensing circuit provides a current feedback signal to the oscillator that is representative of the current in the resonant tank circuit. The current feedback signal drives the frequency of the ballast circuit causing the ballast circuit to seek resonance. The ballast circuit preferably includes a current limit circuit that is inductively coupled to the resonant tank circuit. The current limit circuit disables the ballast circuit when the current in the ballast circuit exceeds a predetermined threshold or falls outside a predetermined range.
1. A ballast circuit comprising:an electromagnetic radiation emitting assembly comprising a secondary coil; andan electronic assembly comprising an inductive coupler, said inductive coupler separated from said electromagnetic radiation emitting assembly by an air gap, aid inductive coupler operable
1. A ballast circuit comprising:an electromagnetic radiation emitting assembly comprising a secondary coil; andan electronic assembly comprising an inductive coupler, said inductive coupler separated from said electromagnetic radiation emitting assembly by an air gap, aid inductive coupler operable to induce a voltage in said secondary coil when said electronic assembly is energized, wherein a permeance of said air gap is adjustable as a function of a distance between said inductive coupler and said secondary coil, an operating point of said electromagnetic radiation emitting assembly adjustable as a function of said permeance. 2. The ballast circuit of claim 1, wherein said inductive coupler comprises inductive impedance in a series resonance tank circuit. 3. The ballast circuit of claim 1, wherein said inductive coupler is operable to generate an alternating flux in said air gap, said alternating flux operable to induce voltage in said secondary coil. 4. The ballast circuit of claim 1, wherein said air gap is operable to provide a mutual flux path between said inductive coupler and said secondary coil. 5. The ballast circuit 1 , wherein said air gap is operable to perform a current limiting function. 6. The ballast circuit of claim 1, wherein said inductive coupler and said secondary coil operably cooperate to form an air core transformer. 7. The ballast circuit of claim 1, wherein said electromagnetic radiation emitting assembly further comprises a resonance lamp circuit and an electromagnetic radiation emitting device. 8. The ballast circuit of claim 1, wherein said electronic assembly further comprises an oscillator, a driver, a half-bridge switching circuit and a series resonant tank circuit. 9. A ballast circuit comprising:an electromagnetic radiation emitting assembly comprising a secondary coil electrically connected with an electromagnetic radiation emitting device;a series resonant tank circuit comprising an inductive coupler, said inductive coupler and said secondary coil operable to form an air core transformer to inductively couple said electromagnetic radiation emitting assembly and said series resonant tank circuit, said secondary coil and said inductive coupler forming a coupling coefficient, an operating point of said electromagnetic radiation emitting device being adjustable as a function of said coupling coefficient;a half bridge switching circuit tank circuit;a driver electrically connected with said half bridge switching circuit; andan oscillator electrically connected with said driver and said series resonant tank circuit, said oscillator operable to direct said half bridge switching circuit with id driver to energize said series resonant tank circuit as a function of feedback from said series resonant tank circuit, said series resonant tank circuit operable to inductively energize said electromagnetic radiation emitting device. 10. The ballast circuit of claim 9, wherein said electromagnetic radiation emitting assembly further comprises a resonant lamp circuit electrically connected with said secondary coil and said electromagnetic radiation emitting device. 11. The ballast circuit of claim 9, wherein a resonant frequency of said series resonant tank circuit and said electromagnetic radiation emitting assembly are substantially equal so as to optimize power transfer with said air core transformer. 12. The ballast circuit of claim 9, wherein said series resonant tank circuit further comprises a tank capacitor, a resonant frequency for said ballast circuit determined as a function of said inductive coupler, said tank capacitor and said electromagnetic radiation emitting assembly. 13. The ballast circuit of claim 9, wherein said electromagnetic radiation emitting assembly further comprises a capacitor, said capacitor electrically connected in series with said electromagnetic radiation emitting device to impedance match said electromagnetic emitting assembly and said series resonant tank circuit. 14. The b allast circuit of claim 9, wherein said electromagnetic radiation emitting assembly further comprises a starter circuit electrically connected with aid electromagnetic radiation emitting device, said starter circuit independently coupled to function as a short for a predetermined time constant when said electromagnetic radiation emitting device is inductively energized. 15. The ballast circuit of claim 9, wherein said electromagnetic radiation emitting assembly further comprises a starter circuit electrically connected with said secondary coil and said electromagnetic radiation emitting device, said starter circuit directed by an external control mechanism absent conductors. 16. The ballast circuit of claim 15, wherein said external control mechanism is operable to direct said starter circuit with at least one of optical control signals, radio frequency control signals and electromagnetic control signals. 17. The ballast circuit of claim 9, wherein said ballast circuit is operable to self oscillate to maintain resonate frequency as a function of reflected impedance of said electromagnetic radiation emitting assembly. 18. The ballast circuit of claim 9, wherein said ballast circuit is operable in a water treatment system. 19. A method of energizing an electromagnetic radiation emitting device as a load, the method comprising:energizing a switching circuit;energizing a tank circuit with an output of the switching circuit to generate a voltage across an inductive coupler;inducing a voltage in a secondary winding with said inductive coupler, said secondary winding separated by an air gap from said inductive coupler;energizing the load with the voltage induced in said secondary winding; andchanging the distance between said inductive coupler and said secondary coil to adjust a coupling coefficient, wherein an operating point of the load is adjustable a function of said coupling coefficient. 20. The method of claim 19, wherein energizing the switching circuit comprises controlling energization of said switching circuit with a feedback signal from said tank circuit to maximize power transfer. 21. The method of claim 19, comprising an initial step of impedance matching said tank circuit and said secondary coil with a capacitor connected in series with said load. 22. The method of claim 21, wherein energizing a tank circuit with an output of the switching circuit to generate voltage across an inductive coupler comprises energizing said tank circuit at a resonant frequency of said secondary coil, said capacitor and said load. 23. The method of claim 19, wherein energizing load with voltage induced in said secondary winding comprises shorting a starter circuit electrically connected in series with said load for a predetermined time to maximize current in said secondary coil during startup absent control external to said starter circuit. 24. The method of claim 19, wherein inducing voltage in a secondary winding with said inductive coupler comprises performing current limiting as a function of said air gap. 25. The method of claim 19, wherein inducing voltage in a secondary winding with said inductive coupler comprises forming an air core transformer with said inductive coupler and said secondary winding. 26. The method of claim 19, wherein inducing voltage in a secondary winding with said inductive coupler comprises generating an alternating flux in said air gap. 27. The method of claim 19, wherein energizing a tank circuit with an output of the switching circuit to generate voltage across an inductive coupler comprises oscillating the frequency of said voltage applied across said inductive coupler as a function of impedance reflected by said load to said tank circuit. 28. A ballast circuit comprising:an oscillator;a driver electrically connected with said oscillator, wherein an output from said oscillator controls said driver;a switching circuit electrically connected with said driver, wherein an output of said driver controls said swit ching circuit;a resonant tank circuit electrically connected with said switching circuit, wherein said resonant tank circuit includes a primary coil; anda current sensing transformer coupled with said oscillator and said resonant tank circuit, said current sensing transformer sensing current in said resonant tank circuit and providing an input to said oscillator as a function of said sensed current. 29. The ballast circuit of claim 28 wherein said switching circuit is a half-bridge switching circuit. 30. The ballast circuit of claim 28 wherein said resonant tank circuit is a series resonant tank circuit. 31. The ballast circuit of claim 28 wherein said resonant tank circuit is a parallel resonant tank circuit. 32. The ballast circuit of claim 28 wherein said current sensing transformer is coupled to a pair of primary coils in said resonant tank circuit. 33. The ballast circuit of claim 32 wherein said resonant tank circuit is a series resonant tank circuit including an inductive coupler and a pair of tank capacitors. 34. The ballast circuit of claim 33 wherein said switching circuit is a half-bridge switching circuit including a pair of secondary coils and a pair of transistors, said secondary coils being opposite in polarity to provide alternating operation of said transistors. 35. The ballast circuit of claim 34 wherein said half-bridge switching circuit is electrically connected to said series resonant circuit wherein alternating operation of said transistors alternately charges and discharges said tank capacitors. 36. The ballast circuit of claim 35 wherein said current sensing g transformer is coupled to said ballast circuit between said switching circuit and said primary coil. 37. The ballast circuit of claim 28 further comprising a current limit circuit. 38. The ballast circuit of claim 37 wherein said current limit circuit includes an operational amplifier, said current sensing transformer being electrically connected to a first input of said operational amplifier of said current limit circuit. 39. The ballast circuit of claim 38 wherein said current limit circuit includes a reference signal electrically connected to a second input of said operational amplifier of said current limit circuit, said reference signal corresponding to a desired threshold value. 40. The ballast circuit of claim 39 further including a control circuit for enabling and disabling said ballast circuit; andwherein said current limit circuit includes a latch having an output electrically connected to said control circuit, said control circuit enabling and disabling said ballast circuit in response to said output received from said latch, an output of said operational amplifier of said current limit circuit being electrically connected to an input of said latch. 41. The ballast circuit of claim 40 wherein said current limit circuit includes a reset for resetting said latch. 42. The ballast circuit of claim 41 wherein said latch is a flip flop. 43. The ballast circuit of claim 42 wherein said current sensing transformer of said current sensing circuit includes a secondary coil wrapped around a core, said current sensing transformer of said current limit circuit including a secondary coil wrapped around said core. 44. A ballast circuit comprising:a control circuit;an oscillator electrically connected with said control circuit;a driver electrically connected with said oscillator, wherein an output from said oscillator controls said driver;a switching circuit electrically connected with said driver, wherein an output of said driver controls said switching circuit;a resonant tank circuit electrically connected with said switching circuit, wherein said resonant tank circuit includes a primary coil;a current sensing circuit electrically connected with said oscillator and said resonant tank circuit, the current sensing circuit including a current sense transformer, said current sensing circuit sensing current in said resonant tank circuit and providing an i nput to said oscillator as a function of said sensed current; anda current limit circuit inductively coupled to said resonant tank circuit and electrically connected to said control circuit, wherein said control circuit disables the ballast circuit in response to a predetermined signal from said current limit circuit. 45. The ballast circuit of claim 44 wherein said current limit circuit includes an operational amplifier, said current sensing transformer being electrically connected to a first input of said operational amplifier of said current limit circuit. 46. The ballast circuit of claim 45 wherein said current limit circuit includes a reference signal electrically connected to a second input of said operational amplifier of said current limit circuit, said reference signal corresponding to a desired threshold value. 47. The ballast circuit of claim 46 wherein said current limit circuit includes a latch having an output electrically connected to said control circuit, said control circuit enabling and disabling said ballast circuit in response to the output received from said latch. 48. The ballast of claim 47 wherein an output of said operational amplifier of said current limit circuit is electrically connected to an input of said latch. 49. The ballast of claim 48 wherein said operational amplifier provides a signal output when said first input exceeds said second input. 50. The ballast circuit of claim 49 wherein said current limit circuit includes a reset for resetting said latch. 51. The ballast circuit of claim 50 wherein said latch is a flip flop. 52. The ballast circuit of claim 51 wherein said current sensing transformer of said current sensing circuit includes a secondary coil wrapped around a core, said current sensing transformer of said current limit circuit including a secondary coil wrapped around said core. 53. The ballast circuit of claim 44 wherein said resonant tank circuit is a series resonant tank circuit. 54. The ballast circuit of claim 44 wherein said resonant tank circuit is a parallel resonant tank circuit. 55. The ballast circuit of claim 44 wherein said resonant tank circuit is a series resonant tank circuit including an inductive coupler and a pair of tank capacitor. 56. The ballast circuit of claim 55 wherein said switching circuit is a half-bridge switching circuit. 57. The ballast circuit of claim 55 wherein said switching circuit is a half-bridge switching circuit including a pair of secondary coils and a pair of transistors, each of said secondary coils being uniquely electrically connected with one of said pair of transistors, said secondary coils being opposite in polarity to provide alternating operation of sa d transistors. 58. The ballast circuit of claim 44 wherein said current sensing g circuit includes a current sensing transformer coupled to said resonant tank circuit. 59. The ballast circuit of claim 58 wherein said half-bridges switching circuit is electrically connected to said series resonant circuit wherein alternating operation n of said transistors alternately charges and discharges said tank capacitors.
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