Inductive load driver utilizing energy recovery
First Claim
Patent Images
1. An inductive load driver comprising:
- an inductive load;
a bridge circuit connected in parallel with said inductive load, wherein said bridge circuit generates a current to said inductive load that rises, the bridge circuit having at least one switch;
a detector connected to said inductive load so as to measure a parameter of said inductive load; and
a controller that is connected to the at least one switch and the detector, wherein the controller opens or closes the at least one switch based upon the measured parameter of said inductive load.
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Abstract
An inductive load driver having an inductive load and a bridge circuit connected in parallel with the inductive load, wherein the bridge circuit generates a current to the inductive load that rapidly rises.
16 Citations
80 Claims
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1. An inductive load driver comprising:
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an inductive load;
a bridge circuit connected in parallel with said inductive load, wherein said bridge circuit generates a current to said inductive load that rises, the bridge circuit having at least one switch;
a detector connected to said inductive load so as to measure a parameter of said inductive load; and
a controller that is connected to the at least one switch and the detector, wherein the controller opens or closes the at least one switch based upon the measured parameter of said inductive load. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
a first diode that is connected to a third leg of said bridge circuit; and
a second diode that is connected to a fourth leg of said bridge circuit.
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6. The inductive load driver of claim 1, comprising:
an independent voltage source that is connected in parallel to said bridge circuit.
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7. The inductive load driver of claim 6, wherein said independent voltage source comprises a battery.
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8. The inductive load driver of claim 1, comprising an independent voltage source connected to a first leg of said bridge circuit.
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9. The inductive load driver of claim 8, wherein said independent voltage source comprises a battery.
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10. The inductive load driver of claim 1, wherein said generated current rises to a peak value in less than 200 μ
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11. The inductive load driver of claim 4, wherein
the controller is connected to said first switch, said second switch and said detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said inductive load. -
12. The inductive load driver of claim 4, further comprising:
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a capacitor that is located in the middle of said bridge circuit; and
a second detector that is connected to said capacitor so as to measure a parameter of said capacitor;
wherein the controller is connected to said first switch, said second switch and said second detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said capacitor.
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13. The inductive load driver of claim 11, further comprising:
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a capacitor is located in the middle of said bridge circuit; and
a second detector that is connected to said capacitor so as to measure a parameter of said capacitor;
wherein said controller opens or closes said first and second switches based upon said measured parameter of said capacitor.
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14. An inductive load driver comprising:
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a bridge circuit;
an inductive load connected in parallel with said bridge circuit, wherein said load is always directly or indirectly ground referenced; and
a detector connected to said inductive load so as to measure a parameter of said load continuously. - View Dependent Claims (15, 16, 17, 18, 19, 20, 21, 22, 23, 24)
a first switch that is connected to a first leg of said bridge circuit; and
a second switch that is connected to a second leg of said bridge circuit, wherein said first leg is opposite said second leg.
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18. The inductive load driver of claim 17, comprising:
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a first diode that is connected to a third leg of said bridge circuit; and
a second diode that is connected to a fourth leg of said bridge circuit.
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19. The inductive load driver of claim 14, wherein said parameter is the current flowing through said load.
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20. The inductive load driver of claim 17, comprising:
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a detector connected to said load so as to measure a parameter of said load; and
a controller that is connected to said first switch, said second switch and said detector, wherein said controller opens or closes said first and second switches based upon said measured parameter.
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21. The inductive load driver of claim 17, comprising:
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a detector connected to said capacitor so as to measure a parameter of said capacitor; and
a controller that is connected to said first switch, said second switch and said detector, wherein said controller opens or closes said first and second switches based upon said measured parameter.
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22. The inductive load driver of claim 21, comprising:
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a detector connected to said capacitor so as to measure a parameter of said capacitor; and
wherein said controller opens or closes said first and second switches based upon said measured parameter of said capacitor.
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23. The inductive load driver of claim 14, comprising:
an independent voltage source that is connected in parallel to said bridge circuit.
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24. The inductive load driver of claim 23, wherein said independent voltage source comprises a battery.
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25. An inductive load driver comprising:
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an inductive load;
a bridge circuit comprising an energy storage element and at least one switch, wherein said bridge circuit is connected in parallel with said inductive load and said energy storage element is not permanently ground referenced;
a detector connected to said inductive load so as to measure a parameter of said inductive load; and
a controller that is connected to the at least one switch and the detector, wherein the controller opens and closes the at least one switch based upon the measured parameter of said inductive load. - View Dependent Claims (26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38)
a first diode that is connected to a third leg of said bridge circuit; and
a second diode that is connected to a fourth leg of said bridge circuit.
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32. The inductive load driver of claim 25, comprising:
a detector connected to said load so as to measure a parameter of said load continuously.
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33. The inductive load driver of claim 32, wherein said parameter is the current flowing through said load.
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34. The inductive load driver of claim 30, wherein
the controller is connected to said first switch, said second switch and said detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said inductive load. -
35. The inductive load driver of claim 30, further comprising:
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a second detector that is connected to said energy storage element so as to measure a parameter of said energy storage element;
wherein the a controller is connected to said first switch, said second switch and said second detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said energy storage element.
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36. The inductive load driver of claim 34, comprising:
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a second detector that is connected to said energy storage element so as to measure a parameter of said energy storage element;
wherein said controller opens or closes said first and second switches based upon said measured parameter of said energy storage element.
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37. The inductive load driver of claim 29, comprising:
an independent voltage source that is connected in parallel to said bridge circuit.
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38. The inductive load driver of claim 37, wherein said independent voltage source comprises a battery.
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39. A method of driving an inductive load that is connected to a bridge circuit, the bridge circuit having at least one switch and a capacitor, the method comprising steps of:
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charging said capacitor with a charge;
measuring a parameter of said inductive load; and
controlling the opening and closing of the at least one switch of said bridge circuit based on the measured parameter of said inductive load so that said charge is dissipated from said capacitor so as to create a first current that drives said inductive load, wherein said inductive load is connected in parallel with said bridge circuit. - View Dependent Claims (40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52)
measuring a parameter of said capacitor; and
performing said controlling of the opening and closing of the at least one switch of said bridge circuit based upon the value of said measured parameter of said capacitor.
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49. The method of claim 42, comprising:
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measuring a parameter of said capacitor; and
performing said controlling of the opening and closing of the at least one switch of said bridge circuit so that said inductive load discharges a charge onto said capacitor based upon the value of said measured parameter of said capacitor.
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50. The method of claim 42, comprising:
performing said controlling of the opening and closing of the at least one switch of said bridge circuit so that said inductive load slowly discharges its stored energy with no energy transfer between said inductive load and said capacitor based upon the value of said measured parameter of said inductive load.
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51. The method of claim 42, comprising:
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measuring a parameter of said capacitor; and
performing said controlling of the opening and closing of the at least one switch of said bridge circuit so that said inductive load slowly discharges its stored energy with no energy transfer between said inductive load and said capacitor based upon the value of said measured parameter of said capacitor.
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52. The method of claim 50, comprising:
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measuring a parameter of said capacitor; and
performing said controlling of the opening and closing of the at least one switch of said bridge circuit so that said inductive load slowly discharges its stored energy with no energy transfer between said inductive load and said capacitor based upon the value of said measured parameter of said capacitor.
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53. A method of driving an inductive load that is connected to a capacitor and a battery comprising:
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driving a current through said inductive load from a first current value to a second current value, wherein said second current value is greater than said first current value;
decreasing the current through said inductive load from said second current value to a third current value, wherein said third current value is greater than said first current value; and
determining whether or not said battery can drive said current from said third current value to said second current value. - View Dependent Claims (54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64)
determining whether or not said capacitor has a voltage that is at least a predetermined value.
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58. The method of claim 57, wherein if it is determined that said battery can drive said current from said third current value to said second current value and said capacitor has a voltage that is at least said predetermined voltage, then said load is freewheeled when said current reaches said second current level.
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59. The method of claim 57, wherein if it is determined that said battery can drive said current from said third current value to said second current value and said capacitor has a voltage that is less than said predetermined voltage, then said load is recovered when said current reaches said second current level.
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60. The method of claim 53, wherein said inductive load is connected in parallel to a bridge circuit.
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61. The method of claim 53, wherein said inductive load comprises a fuel injector.
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62. The method of claim 60, wherein said inductive load comprises a fuel injector.
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63. The method of claim 60, wherein said capacitor is located in the middle of said bridge circuit.
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64. The method of claim 63, wherein said bridge circuit comprises:
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a first switch that is connected to a first leg of said bridge circuit; and
a second switch that is connected to a second leg of said bridge circuit, wherein said first leg is opposite said second leg.
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65. An inductive load driver comprising:
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an inductive load;
a bridge circuit connected in parallel with said inductive load, wherein said bridge circuit generates a current to said inductive load that rises, the bridge circuit having at least one switch and an energy storage element;
a detector connected to said energy storage element so as to measure a parameter of said energy storage element; and
a controller that is connected to the at least one switch and the detector, wherein the controller opens or closes the at least one switch based upon the measured parameter of said energy storage element. - View Dependent Claims (66, 67, 68, 69, 70, 71, 72)
a first diode that is connected to a third leg of said bridge circuit; and
a second diode that is connected to a fourth leg of said bridge circuit.
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69. The inductive load driver of claim 65, further comprising:
an independent voltage source that is connected in parallel to said bridge circuit.
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70. The inductive load driver of claim 65, further comprising an independent voltage source that is connected to a first leg of said bridge circuit.
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71. The inductive load driver of claim 67, wherein the controller is connected to said first switch, said second switch and said detector;
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wherein said controller opens or closes said first and second switches based upon said measured parameter of said energy storage element.
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72. The inductive load driver of claim 67, further comprising:
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a second detector that is connected to said inductive load so as to measure a parameter of said inductive load;
wherein the controller is connected to said first switch, said second switch and said second detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said inductive load.
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73. An inductive load driver comprising:
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an inductive load;
a bridge circuit comprising an energy storage element and at least one switch, wherein said bridge circuit is connected in parallel with said inductive load and said energy storage element is not permanently ground referenced;
a detector connected to said energy storage element so as to measure a parameter of said energy storage element; and
a controller that is connected to the at least one switch and the detector, wherein the controller opens and closes the at least one switch based upon the measured parameter of said energy storage element. - View Dependent Claims (74, 75, 76, 77, 78)
a first diode that is connected to a third leg of said bridge circuit; and
a second diode that is connected to a fourth leg of said bridge circuit.
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77. The inductive load driver of claim 75, further comprising:
a second detector connected to said inductive load so as to measure a parameter of said inductive load continuously.
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78. The inductive load driver of claim 77, wherein the controller is connected to said first switch, said second switch and said detector, wherein said controller opens or closes said first and second switches based upon said measured parameter of said inductive load.
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79. A method of driving an inductive load that is connected to a bridge circuit, the bridge circuit having at least one switch and a capacitor, the method comprising steps of:
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charging said capacitor with a charge;
measuring a parameter of said capacitor; and
controlling the opening and closing of the at least one switch of said bridge circuit based on the measured parameter of said capacitor so that said charge is dissipated from said capacitor so as to create a first current that drives said inductive load, wherein said inductive load is connected in parallel with said bridge circuit. - View Dependent Claims (80)
measuring a parameter of said inductive load; and
performing said controlling of the opening and closing of the at least one switch of said bridge circuit based upon the value of said measured parameter of said inductive load.
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Specification
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Current AssigneeTemic Automotive of North America, Incorporated (Continental AG)
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Original AssigneeMotorola, Inc. (Motorola Solutions, Inc.)
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InventorsFreeman, James A., Albanese, Salvatore, Seifert, Betty-Rose G.
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Primary Examiner(s)Jackson, Stephen W.
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Application NumberUS09/484,107Time in Patent Office1,243 DaysField of Search361/156, 361/160, 361/115, 361/155, 361/152US Class Current361/156CPC Class CodesF02D 2041/2006 by using a boost capacitorF02D 2041/2041 for controlling the current...F02D 41/20 Output circuits, e.g. for c...H01F 2007/1822 using a capacitor to produc...H01F 7/1883 by steepening leading and t...H01H 47/325 by switching regulator
