Claims
- 1. A repair device for fixing a malfunctioning shunt across a failed filament in a light bulb in a group of series connected miniature decorative bulbs, said device comprising:
a high voltage generator producing electrical signals of a magnitude greater than the standard AC power line voltage and containing sufficient energy to cause a malfunctioning shunt to conduct; a repair mechanism receiving said electrical signals from said high voltage generator and including a contact adapted for connection to a bulb socket of said group of series connected miniature decorative bulbs to supply said pulses to said bulbs.
- 2. The repair device of claim 1, wherein said high-voltage generator is a piezoelectric pulse generator.
- 3. The repair device of claim 1, wherein said high-voltage generator is a battery-powered electrical generator.
- 4. The repair device of claim 1, wherein said high-voltage generator is an AC-powered electrical generator.
- 5. The repair device of claim 1, wherein said high-voltage generator comprises both a piezoelectric pulse generator and an electrically powered pulse generator.
- 6. The repair device of claim 1, wherein said group of series-connected miniature decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, and which includes:
a sensor for sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said sensor and producing an electrical signal representing said field strength; an electrical detector receiving said signal and detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field between two locations adjacent a circuit interruption and producing an output signal when such a change is detected; and a signaling device connected to said detector and producing a signal when said output signal is produced to indicate that said sensor has detected the change so that the circuit interruption can be located and replaced.
- 7. The repair device of claim 6, wherein said signaling device produces a first signal when said sensor is sensing a field strength representative of functioning circuit, and a second signal when said sensor is sensing a field strength representative of an interrupted circuit.
- 8. The repair device of claim 7, wherein said first signal is a beeping sound.
- 9. The repair device of claim 6, wherein said signaling device produces a signal corresponding to the change in strength of the AC electrostatic field.
- 10. The repair device of claim 9, wherein said signaling device is one of a buzzer adapted to emit a buzzing sound that becomes louder as the AC electrostatic field sensed becomes stronger or an LED adapted to emit a light having a brightness that corresponds to the strength of the AC electrostatic field sensed.
- 11. The repair device of claim 6, wherein the circuit interruption being detected is a failed bulb.
- 12. The repair device of claim 6, which includes an electrolytic capacitor connected between said sensor and said detector.
- 13. The repair device of claim 6, wherein said detector is a sample and hold detector circuit that includes means for storing as a reference signal a first signal from said sensor, and means for comparing subsequent signals from said sensor with said reference signal.
- 14. The repair device of claim 6, wherein said sensor comprises a dual antenna.
- 15. The repair device of claim 6, which includes a housing that forms at least one storage compartment so that replacement bulbs and fuses can be stored directly in the repair device.
- 16. The repair device of claim 1, which includes a battery and a manually activated test circuit for indicating whether said battery is operational.
- 17. The repair device of claim 1, which includes a housing that forms at least one storage compartment so that replacement bulbs and fuses can be stored directly in the repair device.
- 18. The repair device of claim 17, wherein said storage compartment includes multiple cavities for separated storage of different components.
- 19. The repair device of claim 1, which includes a bulb-removal tool mounted on said housing to facilitate the removal of a bulb from its socket.
- 20. The repair device of claim 19, wherein said tool includes an aperture formed to fit over and engage a bulb and its base to facilitate pulling said bulb and base out of a socket.
- 21. The repair device of claim 20, which includes a tab at one end of said aperture for engaging a flange on a bulb base, and a cradle shaped to conform to the shape of the adjacent portion of a bulb at the other end of said aperture.
- 22. The repair device of claim 19, which includes a guard extending along and slightly spaced from the leading edge of said tool for safety protection.
- 23. The repair device of claim 1, wherein said housing includes a socket that receives one of said bulbs and connected to an electrical power source so that a functioning bulb inserted into said socket is illuminated.
- 24. The repair device of claim 1, wherein said housing includes a socket that receives a light string fuse and connected to an electrical power source and a good-fuse indicator so that a functioning fuse inserted into said socket activates said good-fuse indicator.
- 25. The repair device of claim 1, which includes a continuity indicator responsive to current flow through a light string connected to said connector for providing an indication that said light string has been repaired.
- 26. The repair device of claim 1, which includes an electrical component connected between said high-voltage generator and said connector for shaping a signal from said generator before said signal is applied to a light string connected to said connector.
- 27. The repair device of claim 26, wherein said signal is a pulse and an impedance is connected between said high-voltage generator and said connector for shaping said pulse stretches said pulse.
- 28. The repair device of claim 26, wherein said electrical component is an impedance connected between said high-voltage generator and said connector for shaping said signal stretches said signal.
- 29. The repair device of claim 1, further including an internal diode connected across the high voltage generator, the internal diode allowing enough energy to flow from a power source coupled to the light string through the light string to illuminate the light string once the malfunctioning shunt has been repaired.
- 30. The repair device of claim 1, which includes a portable housing containing said high-voltage pulse generator and connector, and a self-contained power source.
- 31. The repair device of claim 1, wherein said high-voltage pulse generator is powered by a battery and includes a pulse-triggering device that allows a generated voltage to build up to a preselected level before the pulse is applied to said connector.
- 32. The repair device of claim 1, wherein said high-voltage pulse generator includes a capacitor for accumulating a charge that is used to produce said high-voltage pulse.
- 33. The repair device of claim 1, wherein said high-voltage pulse generator is powered by a battery and includes an electrolytic capacitor for storing energy from said battery for producing a high-voltage pulse.
- 34. The repair device of claim 1, which includes a high-voltage power source capable of making a malfunctioning bulb glow in a light string connected to said connector.
- 35. The repair device of claim 1, which includes an electrical power source and a capacitor storing enough energy that, upon discharge of said capacitor, is capable of making a malfunctioning bulb blink in a light string connected to said connector.
- 36. The repair device of claim 1, which includes a battery power source and a removable holder for said battery.
- 37. The repair device of claim 36, which includes a good-battery indicator and a switch connected in series with said battery and said indicator, and wherein said removable battery holder also forms a manual actuator for said switch.
- 38. The repair device of claim 1, wherein said repair mechanism further comprises an additional plug socket adapted for connection to an electrical plug of said group of series connected miniature decorative bulbs to supply said pulses to said bulbs.
- 39. The repair device of claim 1, further comprising an illuminating LED adapted to illuminate the group of series connected miniature decorative bulbs being fixed.
- 40. A method of fixing a malfunctioning shunt across a failed filament in a light bulb in a group of series-connected miniature decorative bulbs, said method comprising:
producing a high-voltage electrical signal of a magnitude greater than the standard AC power line voltage; and applying said electrical signal to a bulb socket of said group of series-connected miniature decorative bulbs.
- 41. The method of claim 40, wherein said high-voltage electrical signal is produced by a piezoelectric pulse generator.
- 42. The method of claim 40, wherein said high-voltage electrical signal is produced by a battery-powered electrical generator.
- 43. The method of claim 40, wherein said high-voltage electrical signal is produced by an AC-powered electrical generator.
- 44. The method of claim 40, wherein said high-voltage electrical signal is produced by both a piezoelectric pulse generator and an electrically powered electrical signal generator.
- 45. The method of claim 40, wherein said group of series-connected miniature decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, and which includes:
passing a sensor along said wires, sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said sensor and producing an electrical signal representing said field strength; detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field between two locations adjacent a circuit interruption and producing an output signal when such a change is detected; and producing a signal in response to said output signal to indicate that said sensor has detected the change so that the circuit interruption can be located and repaired.
- 46. The method of claim 45, wherein a first signal is produced when said sensor is sensing a field strength representative of functioning bulbs, and a second signal is produced when said sensor is sensing a field strength representative of a circuit interruption.
- 47. The method of claim 46, wherein said circuit interruption is a failed bulb.
- 48. The method of claim 47, wherein producing said signal comprises producing a signal that increases as the strength of the AC electrostatic field increases.
- 49. The method of claim 48, wherein said signal is at least one of a buzzer and an LED.
- 50. The method of claim 45, wherein said sensor is a probe.
- 51. The repair device of claim 45, wherein the sensitivity to different electrostatic field strengths is stabilized by an electrolytic capacitor connected to said probe.
- 52. The method of claim 45, which includes storing as a reference signal a first signal from said probe, and comparing subsequent signals from said probe with said reference signal.
- 53. The method of claim 45, wherein said sensor comprises a dual antenna.
- 54. The method of claim 45, which includes storing replacement bulbs and fuses can be stored directly in the repair device.
- 55. The method of claim 40, which includes supplying electrical power for the detecting and signaling from a battery, and indicating whether said battery is operational.
- 56. The method of claim 40, which includes providing an indication that said light string has been repaired in response to current flow through said light string.
- 57. The method of claim 40, wherein said high-voltage signal is stretched before it is applied to said light string.
- 58. The method of claim 40, wherein said high-voltage signal is shaped before it is applied to said light string.
- 59. The method of claim 40, wherein a generated voltage is allowed to build up to a preselected level before the electrical signal is applied to said light string.
- 60. The method of claim 40, wherein a charge is accumulated in a capacitor and then used to produce said high-voltage electrical signal.
- 61. The method of claim 40, which includes storing energy from a battery in an electrolytic capacitor for producing said high-voltage electrical signal.
- 62. The method of claim 40, which includes supplying high-voltage power to said light string to cause a malfunctioning bulb glow in said light string to glow.
- 63. The method of claim 40, which includes storing in a capacitor enough energy that, upon discharge of said capacitor, a malfunctioning bulb in said light string is caused to blink.
- 64. The method of claim 40, further including illuminating the group of series connected miniature decorative bulbs.
- 65. A repair and test device for a group of series-connected miniature decorative bulbs comprising:
a housing that forms at least one storage compartment so that replacement bulbs and fuses can be stored in said housing; a connector in said housing for connection to a bulb socket of said group of series-connected miniature decorative bulbs; an electrical power source mounted within said housing; means mounted within said housing and connected to said connector for fixing a malfunctioning shunt across a failed filament in a light bulb in said group of series-connected miniature decorative bulbs; and a socket in said housing for receiving one of said bulbs and connected to said electrical power source so that a functioning bulb inserted into said socket is illuminated.
- 66. The repair device of claim 65, wherein said group of series-connected miniature decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, and which includes a probe for sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said probe and producing an electrical signal representing said field strength, an electrical detector receiving said signal and detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field in the vicinity of a failed bulb and producing an output signal when such a change is detected, and a signaling device connected to said detector and producing a visible or audible signal when said output signal is produced to signal that said probe is in the vicinity of a failed bulb so that the failed bulb can be located and replaced.
- 67. A method of initiating the operation of a shunt connected in parallel with a failed filament of a light bulb in a group of series-connected bulbs, said method comprising:
providing a source of high voltage in excess of ordinary power line voltage at limited current; and connecting said high voltage source in series with said series-connected bulbs through a bulb socket to apply a voltage to said series-connected bulbs.
- 68. A repair device for fixing a malfunctioning shunt across a failed filament in a light bulb in a group of series connected miniature decorative bulbs, said device comprising:
a high voltage generator producing electrical signals of a magnitude greater than the standard AC power line voltage and containing sufficient energy to breakdown non-conductive material in the malfunctioning shunt; and a repair mechanism receiving said electrical signals from said high voltage generator and including a contact adapted for connection to said group of series connected miniature decorative bulbs to supply said pulses to said bulbs, said repair mechanism receiving current from an AC source containing sufficient energy to weld the malfunctioning shunt.
- 69. A method of fixing a malfunctioning shunt across a failed filament in a light bulb in a group of series-connected miniature decorative bulbs, the method comprising:
producing a high-voltage electrical signal of a magnitude greater than the standard AC power line voltage; allowing an AC signal producing an electrical waveform to flow through the group of series-connected miniature decorative bulbs; applying said electrical signal to said group of series-connected miniature bulbs so as to breakdown non-conductive material in the malfunctioning shunt; applying said AC signal to said group of series-connected miniature bulbs so as to weld the malfunctioning shunt after the breakdown of the non-conductive material; and illuminating all of the miniature decorative bulbs except for the failed bulb.
- 70. A sensing device for sensing a series circuit interruption in a group of series connected decorative bulbs, wherein said group of series-connected decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, said device comprising:
a dual-antenna sensor for sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said sensor and producing an electrical signal representing said field strength, said dual-antenna sensor including a first antenna and a second antenna; an electrical detector receiving said signal and detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field in the vicinity of a circuit interruption and producing an output signal when such a change is detected; and a signaling device connected to said detector and producing a signal when said output signal is produced to indicate that said sensor is in the vicinity of a circuit interruption so that the corrective action can be taken; wherein the first antenna and the second antenna are spaced such that said dual-antenna sensor can detect a change in field strength by either scanning along the wires or by placing an individual bulb socket of the light string between the first and second antennas and moving the first and second antennas from side to side.
- 71. The sensor of claim 70, wherein said signaling device is an LED.
- 72. The sensor of claim 71, wherein said LED is adapted to be used as a headlamp in a low-light situation, so as to provide light to a user.
- 73. The method of claim 72, wherein said producing a signal comprises producing a light signal.
- 74. The method of claim 73, further comprising producing a light signal having the strength to provide a headlamp in a low-light situation.
- 75. A sensing device for sensing a series circuit interruption in a group of series connected decorative bulbs, said device comprising:
a dual-antenna sensor for sensing the strength of an AC electrostatic field around a portion of said group of decorative bulbs adjacent to said sensor and producing an electrical signal representing said field strength, the dual antenna having a first antenna and a second antenna; an electrical detector receiving said signal and detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field in the vicinity of a circuit interruption and producing an output signal when such a change is detected; and a signaling device connected to said detector and producing or ceasing to produce an indicating signal when said output signal is produced to indicate that said sensor is in the vicinity of a circuit interruption so that the corrective action can be taken; wherein the first and second antennas are spaced such that the dual-antenna sensor can detect the change in field strength by scanning the first and second antennas along the wire and by placing an individual bulb socket between the first and second antennas and moving the first and second antennas from side to side.
- 76. A method of sensing a malfunctioning shunt across a failed filament in a light bulb in a group of series-connected miniature decorative bulbs, wherein said group of series-connected decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, said method comprising:
passing a dual antenna sensor along said wires, sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said sensor and producing an electrical signal representing said field strength, wherein said dual-antenna sensor comprises a first antenna and a second antenna; placing a suspected failed bulb between the first antenna and the second antenna; moving said first and second antenna, so that the socket is adjacent first one of said first antenna and second antenna and then the other of the first antenna and the second antenna; if a failed bulb is between the first and second antennas, said first antenna sensing an AC electrostatic field when said bulb socket is adjacent said first antenna and said second antenna failing to sense an AC electrostatic field when said failed bulb is adjacent said second antenna; and producing an output signal when an AC electrostatic field is sensed and ceasing to produce the output signal when the AC electrostatic field is no longer sensed.
- 77. A sensing device for sensing a series circuit interruption in a group of series connected decorative bulbs, wherein said group of series-connected miniature decorative bulbs is in a light string that includes wires connecting said bulbs to each other and conducting electrical power to said bulbs, said device comprising:
a sensor for sensing the strength of the AC electrostatic field around a portion of said wires adjacent to said sensor and producing an electrical signal representing said field strength, the sensor including a sample and hold circuit; an electrical detector receiving said signal and detecting a change in said signal that corresponds to a change in the strength of said AC electrostatic field between two locations adjacent a circuit interruption and producing an output signal when such a change is detected; and a signaling device connected to said detector and producing a signal when said output signal is produced to indicate that said sensor has detected the change so that the circuit interruption can be located and replaced.
- 78. A kit comprising:
a repair device for fixing a malfunctioning shunt across a failed filament in a light bulb in a group of series connected miniature decorative bulbs; and a storage device for decorative lighting accessories.
- 79. A testing device for testing a light string fuse and a miniature decorative light bulb comprising:
a socket for receiving a light string fuse and a bulb socket of a miniature decorative light bulb, the socket having a first set of contacts for receiving the fuse and a second set of contacts for receiving the bulb socket of the miniature decorative light bulb; an electrical power source connected to said socket and providing power to the first and second set of contacts; and a good fuse indicator connected to said socket and said electrical power source, so that a functioning fuse inserted into said socket activates said good fuse indicator; wherein the electrical power source causes a functioning light bulb to glow if placed in the socket.
- 80. A kit comprising:
a sensing device for testing a malfunctioning shunt across a failed filament in a light bulb in a group of series connected miniature decorative bulbs; and a storage device for decorative lighting accessories.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation in part of U.S. Ser. No. 10/041,032 filed Dec. 28, 2002, claiming priority to U.S. Provisional Application Serial No. 60/277,481 filed Mar. 20, 2001, and to U.S. Provisional Application Serial No. 60/289,865 filed May 9, 2001.
Provisional Applications (2)
|
Number |
Date |
Country |
|
60277481 |
Mar 2001 |
US |
|
60289865 |
May 2001 |
US |
Continuation in Parts (1)
|
Number |
Date |
Country |
Parent |
10041032 |
Dec 2001 |
US |
Child |
10703858 |
Nov 2003 |
US |