What is claimed is:

1 . A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a diverging fuel stream at a distance along the diverging fuel stream corresponding to a desired fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof; and

a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder;

wherein the imparted charge concentration is selected to cause the flame to remain ignited and in contact with the conductive flame holder.

2. The low NOx burner of claim 1 , wherein the distance includes a distance from a fuel nozzle plus a distance to a point upstream from the fuel nozzle.

3. The low NOx burner of claim 1 , wherein the distance corresponds substantially to a lean flammability limit of the fuel in the fuel stream.

4. The low NOx burner of claim 1 , wherein the diverging fuel stream diverges at a substantially 15 degree solid angle.

5. The low NOx burner of claim 1 , wherein the diverging fuel stream diverges at an angle of 7.5° from an axis of fuel transport.

6. The low NOx burner of claim 1 , further comprising:

an adjustable support configured to change the distance at which the conductive flame holder is supported responsive to a change in the lean flammability limit or other operating parameter.

7. The low NOx burner of claim 1 , further comprising: an electronic control module configured to select the distance along the diverging fuel stream at which the conductive flame holder is supported.

8. The low NOx burner of claim 1 , wherein the conductive flame holder is shaped to define an aperture corresponding at least approximately to a fuel stream diameter at the distance.

9. The low NOx burner of claim 1 , wherein the conductive flame holder includes a circular tension conductive structure.

10. The low NOx burner of claim 1 , wherein the conductive flame holder includes a composite assembly configured to adapt the shape of the conductive flame holder to a selected corresponding diverging fuel stream diameter.

1 1 . The low NOx burner of claim 1 , wherein the conductive flame holder includes a plurality of conductive flame holders sized to correspond to respective selected diameters corresponding to the diverging fuel stream.

12. The low NOx burner of claim 1 , wherein the conductive flame holder includes a sharp electrode.

13. The low NOx burner of claim 1 , wherein the conductive flame holder is a substantially dull electrode.

14. The low NOx burner of claim 1 , further comprising:

operatively coupled to or forming a portion of the conductive flame holder, a node having a selected voltage condition.

15. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes a voltage different than the voltage applied to the electrode.

16. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes a second time-varying voltage to the electrically conductive surface, the second time-varying voltage being opposite in sign to a first time- varying voltage applied to the charge source.

17. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes substantially voltage ground.

18. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes electrical isolation from ground and from voltages other than the voltage corresponding to the charges imparted onto the flame.

19. The low NOx burner of claim 1 , further comprising:

a voltage source configured to apply a voltage to the charge source;

wherein the charge source is configured to impart the charge concentration responsive to the applied voltage.

20. The low NOx burner of claim 19, wherein the voltage source is configured to apply a time-varying voltage to the charge source.

21 . The low NOx burner of claim 20, wherein the time-varying voltage includes a periodic voltage waveform having a 50 to 10,000 Hertz frequency.

22. The low NOx burner of claim 20, wherein the time-varying voltage includes a periodic voltage waveform having a 200 to 800 Hertz frequency.

23. The low NOx burner of claim 20, wherein the time-varying voltage includes a square waveform, sine waveform, triangular waveform, truncated triangular waveform, sawtooth waveform, logarithmic waveform, or exponential waveform.

24. The low NOx burner of claim 20, wherein the time-varying voltage includes a waveform having ±1000 volt to ±1 15,000 volt amplitude.

25. The low NOx burner of claim 24, wherein the time-varying voltage includes a waveform having ±8000 volt to ±40,000 volt amplitude.

26. The low NOx burner of claim 1 , wherein the charge source includes a sharp electrode.

27. The low NOx burner of claim 1 , wherein the charge source includes a substantially dull electrode.

28. The low NOx burner of claim 1 , wherein the charge source includes a depletion electrode configured to deplete from the flame ions or electrons having a non-majority charge sign.

29. The low NOx burner of claim 1 , wherein the charge source includes a charge adding apparatus configured to apply the majority charge to the flame.

30. The low NOx burner of claim 1 , wherein the conductive flame holder comprises:

a conductive flame holding surface; and

a conductive flame-holder support mechanically coupled to the conductive flame holding surface and configured for mechanical coupling to another surface.

31 . The low NOx burner of claim 30, further comprising:

a fuel nozzle;

wherein the conductive flame holder support is mechanically coupled to the fuel nozzle.

32. The low NOx burner of claim 31 , wherein the conductive flame holder and the fuel nozzle are mechanically coupled to form an integrated fuel nozzle and conductive flame holder.

33. The low NOx burner of claim 32, wherein the conductive flame holder and the fuel nozzle are joined by one or more of at least one selected from the group comprising threaded fasteners, one or more rivets, one or more weldments, one or more brazed fittings, one or more held-together surfaces, one or more cold- formed joints, one or more pressure-formed angles, one or more co-molded interfaces, one or more sintered shapes, and one or more die-cast features.

34. The low NOx burner of claim 32, wherein the conductive flame holder and the fuel nozzle are formed as a single piece.

35. The low NOx burner of claim 31 , wherein the fuel nozzle is conductive.

36. A method of operating a low oxides of nitrogen (NOx) burner, comprising: supporting a conductive flame holder proximate a diverging fuel stream at a selected distance along the diverging fuel stream; and

imparting a charge onto a flame held by the conductive flame holder and supported by the diverging fuel stream.

37. The method of operating a low NOx burner of claim 36, further comprising: supplying the diverging fuel stream.

38. The method of operating a low NOx burner of claim 36, further comprising: maintaining flame holding and flame ignition responsive to the cooperation between the imparted charge on the flame and the conductive flame holder.

39. The method of operating a low NOx burner of claim 36, further comprising: applying heat from the flame to a heat-receiving surface.

40. The method of operating a low NOx burner of claim 36, wherein the selected distance substantially corresponds to a flammability limit of the fuel.

41 . The method of operating a low NOx burner of claim 40, further comprising: determining the selected distance.

42. The method of operating a low NOx burner of claim 41 wherein

determining the selected distance further comprises:

receiving a signal or operating a sensor to generate a signal indicative of a fuel condition;

calculating or looking up a distance along a stream of the fuel, the distance having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the distance data corresponding to the distance or a signal corresponding to the distance to drive a conductive flame holder support to the distance or outputting an indication of the distance on an instrument for viewing by a user.

43. The method of operating a low NOx burner of claim 41 , further comprising: driving an actuator to support the conductive flame holder at the selected distance along the diverging fuel stream.

44. The method of operating a low NOx burner of claim 36, further comprising: applying a voltage to the charge source;

wherein the charge source imparts the charge concentration responsive to the applied voltage.

45. The method of operating a low NOx burner of claim 44, wherein applying a voltage to the charge source includes applying a time-varying voltage to the charge source.

46. The method of operating a low NOx burner of claim 45, wherein applying a voltage to the charge source includes applying a periodic voltage waveform having a 50 to 10,000 Hertz frequency.

47. The method of operating a low NOx burner of claim 45, wherein applying a voltage to the charge source includes applying a periodic voltage waveform having a 200 to 800 Hertz frequency.

48. The method of operating a low NOx burner of claim 45, wherein applying a voltage to the charge source includes applying a square waveform, sine waveform, triangular waveform, truncated triangular waveform, sawtooth waveform, logarithmic waveform, or exponential waveform.

49. The method of operating a low NOx burner of claim 45, wherein applying a voltage to the charge source includes applying a waveform having ±1000 volt to ±1 15,000 volt amplitude.

50. The method of operating a low NOx burner of claim 49, wherein applying a voltage to the charge source includes applying a waveform having ±8000 volt to ±40,000 volt amplitude.

51 . The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a sharp electrode proximate to the flame.

52. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a substantially dull electrode proximate to the flame.

53. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a depletion electrode configured to deplete from the flame ions or electrons having a non-majority charge sign.

54. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a charge adding apparatus configured to apply the majority charge to the flame.

55. The method of operating a low NOx burner of claim 36, further comprising: applying or maintaining a voltage condition to the conductive flame holder.

56. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes applying a voltage different than a voltage applied to a charge source that imparts the charge onto the flame.

57. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes a applying a second time-varying voltage to the electrically conductive surface, the second time-varying voltage being opposite in sign to the charge imparted onto the flame.

58. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes maintaining substantially voltage ground.

59. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes maintaining electrical isolation from ground and from voltages other than the voltage corresponding to the charges imparted onto the flame.

60. A method of determining a distance along a fuel stream for supporting a conductive flame holder, comprising:

receiving a signal or operating a sensor to generate a signal indicative of a fuel condition;

calculating or looking up a distance along a stream of the fuel, the distance having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the distance data corresponding to the distance or a signal corresponding to the distance to drive a conductive flame holder support to the distance or outputting an indication of the distance on an instrument for viewing by a user.

61 . A non-transitory computer readable media carrying computer executable instructions configured to cause an electronic control module to perform a method comprising the steps of:

receiving a signal or operating a sensor to generate a signal indicative of a fuel condition;

calculating or looking up a distance along a stream of the fuel, the distance having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the distance data corresponding to the distance or a signal corresponding to the distance to drive a conductive flame holder support to the distance or outputting an indication of the distance on an instrument for viewing by a user.

received by the International Bureau on 14 November 2013 (14.1 1.2013)

1. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof; and a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder, the imparted charge concentration being selected to cause the flame to remain ignited and in contact with the conductive flame holder.

2. The low NOx burner of claim 1 , wherein the position includes a distance from a fuel nozzle plus a distance to a point upstream from the fuel nozzle.

3. The low NOx burner of claim 1 , wherein the position corresponds substantially to a lean flammability limit of the fuel in the fuel stream.

4. The low NOx burner of claim 1 , wherein the diverging fuel stream diverges at a substantially 15 degree solid angle.

5. The low NOx burner of claim 1 , wherein the diverging fuel stream diverges at an angle of 7.5° from an axis of fuel transport.

6. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof; a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder; and

an adjustable support configured to change the position at which the conductive flame holder is supported responsive to a change in the lean flammability limit or other operating parameter.

7. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof; a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder; and

an electronic control module configured to select the position along the diverging fuel stream at which the conductive flame holder is supported.

8. The low NOx burner of claim 1 , wherein the conductive flame holder is shaped to define an aperture corresponding at least approximately to a fuel stream diameter at theposition.

9. The low NOx burner of claim 1 , wherein the conductive flame holder includes a circular tension conductive structure.

10. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof, the conductive flame holder including a composite assembly configured to adapt the shape of the conductive flame holder to a selected corresponding diverging fuel stream diameter; and a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder.

1 1 . A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof, the conductive flame holder including a plurality of conductive flame holders sized to correspond to respective selected diameters corresponding to the diverging fuel stream; and

a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder.

12. The low NOx burner of claim 1 , wherein the conductive flame holder includes a sharp electrode.

13. The low NOx burner of claim 1 , wherein the conductive flame holder is a substantially dull electrode.

14. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof; a node, operatively coupled to or forming a portion of the conductive flame holder and having a selected voltage condition a charge source configured to impart a charge

concentration on a flame surface held by the conductive flame holder, the charge concentration being selected to cause the flame to remain ignited and in contact with the conductive flame holder.

15. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes a voltage different than the voltage applied to the electrode.

16. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes a second time-varying voltage to the electrically conductive surface, the second time- varying voltage being opposite in sign to a first time-varying voltage applied to the charge source.

17. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes substantially voltage ground.

18. The low NOx burner of claim 14, wherein the selected voltage condition of the node includes electrical isolation from ground and from voltages other than the voltage corresponding to the charges imparted onto the flame.

19. The low NOx burner of claim 1 , further comprising:

a voltage source configured to apply a voltage to the charge source; wherein the charge source is configured to impart the charge concentration responsive to the applied voltage.

20. The low NOx burner of claim 19, wherein the voltage source is configured to apply a time-varying voltage to the charge source.

21 . The low NOx burner of claim 20, wherein the time-varying voltage includes a periodic voltage waveform having a 50 to 10,000 Hertz frequency.

22. The low NOx burner of claim 20, wherein the time-varying voltage includes a periodic voltage waveform having a 200 to 800 Hertz frequency.

23. The low NOx burner of claim 20, wherein the time-varying voltage includes a square waveform, sine waveform, triangular waveform, truncated triangular waveform, sawtooth waveform, logarithmic waveform, or exponential waveform.

24. The low NOx burner of claim 20, wherein the time-varying voltage includes a waveform having ±1000 volt to ±1 15,000 volt amplitude.

25. The low NOx burner of claim 24, wherein the time-varying voltage includes a waveform having ±8000 volt to ±40,000 volt amplitude.

26. The low NOx burner of claim 1 , wherein the charge source includes a sharp electrode.

27. The low NOx burner of claim 1 , wherein the charge source includes a substantially dull electrode.

28. The low NOx burner of claim 1 , wherein the charge source includes a depletion electrode configured to deplete from the flame ions or electrons having a non-majority charge sign.

29. The low NOx burner of claim 1 , wherein the charge source includes a charge adding apparatus configured to apply the majority charge to the flame.

30. A low oxides of nitrogen (NOx) burner, comprising:

a conductive flame holder supported proximate a nozzle configured to produce a diverging fuel stream, at a position along the diverging fuel stream corresponding to a selected fuel concentration, oxygen concentration, fuel/oxygen stoichiometry, or combination thereof, the conductive flame holder including:

a conductive flame holding surface, and

a conductive flame-holder support mechanically coupled to the conductive flame holding surface and configured for mechanical coupling to another surface; and

a charge source configured to impart a charge concentration on a flame surface held by the conductive flame holder, the imparted charge concentration being selected to cause the flame to remain ignited and in contact with the conductive flame holder.

31 . The low NOx burner of claim 30, further comprising:

a fuel nozzle;

wherein the conductive flame holder support is mechanically coupled to the fuel nozzle.

32. The low NOx burner of claim 31 , wherein the conductive flame holder and the fuel nozzle are mechanically coupled to form an integrated fuel nozzle and conductive flame holder.

33. The low NOx burner of claim 32, wherein the conductive flame holder and the fuel nozzle are joined by one or more of at least one selected from the group comprising threaded fasteners, one or more rivets, one or more weldments, one or more brazed fittings, one or more held-together surfaces, one or more cold-formed joints, one or more pressure-formed angles, one or more co-molded interfaces, one or more sintered shapes, and one or more die-cast features.

34. The low NOx burner of claim 32, wherein the conductive flame holder and the fuel nozzle are formed as a single piece.

35. The low NOx burner of claim 31 , wherein the fuel nozzle is conductive.

36. A method of operating a low oxides of nitrogen (NOx) burner, comprising: supporting a conductive flame holder proximate a diverging fuel stream at a position along the diverging fuel stream that substantially corresponds to a flammability limit of the fuel; and

imparting a charge onto a flame held by the conductive flame holder and supported by the diverging fuel stream.

37. The method of operating a low NOx burner of claim 36, further comprising:

supplying the diverging fuel stream.

38. The method of operating a low NOx burner of claim 36, further comprising:

maintaining flame holding and flame ignition responsive to the cooperation between the imparted charge on the flame and the conductive flame holder.

39. The method of operating a low NOx burner of claim 36, further comprising:

applying heat from the flame to a heat-receiving surface.

41 . The method of operating a low NOx burner of claim 40, further comprising:

determining the selected distance.

42. The method of operating a low NOx burner of claim 41 wherein determining the selected position further comprises:

receiving a signal or operating a sensor to generate a signal indicative of a fuel condition;

calculating or looking up a position along a stream of the fuel, the position having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the position data corresponding to the position or a signal corresponding to the position to drive a conductive flame holder support to the position or outputting an indication of the position on an instrument for viewing by a user.

43. The method of operating a low NOx burner of claim 41 , further comprising:

driving an actuator to support the conductive flame holder at the selected position along the diverging fuel stream.

44. The method of operating a low NOx burner of claim 36, further comprising: applying a voltage to the charge source;

wherein the charge source imparts the charge concentration responsive to the applied voltage.

45. The method of operating a low NOx burner of claim 44, wherein applying a voltage to th charge source includes applying a time-varying voltage to the charge source.

46. The method of operating a low NOx burner of claim 45, wherein applying a voltage to th charge source includes applying a periodic voltage waveform having a 50 to 10,000 Hertz frequency.

47. The method of operating a low NOx burner of claim 45, wherein applying a voltage to th charge source includes applying a periodic voltage waveform having a 200 to 800 Hertz frequency.

48. The method of operating a low NOx burner of claim 45, wherein applying a voltage to th charge source includes applying a square waveform, sine waveform, triangular waveform, truncated triangular waveform, sawtooth waveform, logarithmic waveform, or exponential waveform.

49. The method of operating a low NOx burner of claim 45, wherein applying a voltage to th charge source includes applying a waveform having ±1000 volt to ±1 15,000 volt amplitude.

50. The method of operating a low NOx burner of claim 49, wherein applying a voltage to th charge source includes applying a waveform having ±8000 volt to ±40,000 volt amplitude.

51 . The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a sharp electrode proximate to the flame.

52. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a substantially dull electrode proximate to the flame.

53. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a depletion electrode configured to deplete from the flame ions or electrons having a non-majority charge sign.

54. The method of operating a low NOx burner of claim 36, wherein imparting a charge includes applying a voltage to a charge adding apparatus configured to apply the majority charge to the flame.

55. The method of operating a low NOx burner of claim 36, further comprising:

applying or maintaining a voltage condition to the conductive flame holder.

56. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes applying a voltage different than a voltage applied to a charge source that imparts the charge onto the flame.

57. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes a applying a second time-varying voltage to the electrically conductive surface, the second time-varying voltage being opposite in sign to the charge imparted onto the flame.

58. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes maintaining substantially voltage ground.

59. The method of operating a low NOx burner of claim 55, wherein applying or maintaining a voltage condition to the conductive flame holder includes maintaining electrical isolation from ground and from voltages other than the voltage corresponding to the charges imparted onto the flame.

60. A method of determining a position along a fuel stream for supporting a conductive flame holder, comprising:

receiving a signal or operating a sensor to generate a signal indicative of a fuel condition; calculating or looking up a position along a stream of the fuel, the position having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the position data corresponding to the position or a signal corresponding to the position to drive a conductive flame holder support to the position or outputting an indication of the position on an instrument for viewing by a user.

61 . A non-transitory computer readable media carrying computer executable instructions configured to cause an electronic control module to perform a method comprising the steps of: receiving a signal or operating a sensor to generate a signal indicative of a fuel condition;

calculating or looking up a position along a stream of the fuel, the position having a relationship to a lean flammability limit corresponding to the fuel condition; and

outputting the position data corresponding to the position or a signal corresponding to the position to drive a conductive flame holder support to the position or outputting an indication of the position on an instrument for viewing by a user.

62. The low NOx burner of claim 6, wherein the imparted charge concentration is selected to cause the flame to remain ignited and in contact with the conductive flame holder.

63. The low NOx burner of claim 7, wherein the imparted charge concentration is selected to cause the flame to remain ignited and in contact with the conductive flame holder.

64. The low NOx burner of claim 10, wherein the imparted charge concentration is selected to cause the flame to remain ignited and in contact with the conductive flame holder.

65. The low NOx burner of claim 1 1 , wherein the imparted charge concentration is selected to cause the flame to remain ignited and in contact with the conductive flame holder.