Electrical integrity test system for boats

US 6,265,879 B1
Filed: 07/14/1999
Issued: 07/24/2001
Est. Priority Date: 07/14/1999
Status: Expired due to Fees

First Claim

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1. An apparatus for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator having series semi-conductors, normally operative and arranged to block passage of DC currents in both directions and to permit passage of AC currents in both directions and to permit passage of AC currents through the galvanic isolator to earth ground, said apparatus comprising:

a) means for applying a DC voltage of selected first polarity across a first silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;

b) means for applying a DC voltage of said first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;

c) means for comparing the voltage drop across said galvanic isolator with said voltage drop across said first silicon diode reference semi-conductor;

d) means for applying a DC voltage of selected second polarity opposite said first polarity across a second silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;

e) means for applying a DC voltage of said second polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;

f) means for comparing the voltage drop across said second silicon diode reference semi-conductor with said voltage drop across said galvanic isolator; and

g) means for indicating whether the voltage drops corresponding to application of said DC voltages of said first and second polarities across said galvanic isolator and across said first and second silicon diode reference semi-conductors correspond to what would be normally expected.

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Abstract

An electrical integrity test system for boats provides circuitry for evaluating the integrity of the boat'"'"'s galvanic isolator. The integrity test system includes two single reference diodes and a circuit for applying DC voltages across said reference diodes and said galvanic isolator. Another micro-controller stores the values of the voltage drops across the galvanic isolator and the voltage drops across each reference diode and subsequently determines if the voltage drop across the galvanic isolator is that to be normally expected. If it is not, then the system informs the operator that the boat'"'"'s galvanic isolator is not operating properly.

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26 Claims

1. An apparatus for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator having series semi-conductors, normally operative and arranged to block passage of DC currents in both directions and to permit passage of AC currents in both directions and to permit passage of AC currents through the galvanic isolator to earth ground, said apparatus comprising:
- a) means for applying a DC voltage of selected first polarity across a first silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  b) means for applying a DC voltage of said first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  c) means for comparing the voltage drop across said galvanic isolator with said voltage drop across said first silicon diode reference semi-conductor;
  
  d) means for applying a DC voltage of selected second polarity opposite said first polarity across a second silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  e) means for applying a DC voltage of said second polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  f) means for comparing the voltage drop across said second silicon diode reference semi-conductor with said voltage drop across said galvanic isolator; and
  
  g) means for indicating whether the voltage drops corresponding to application of said DC voltages of said first and second polarities across said galvanic isolator and across said first and second silicon diode reference semi-conductors correspond to what would be normally expected.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 18, 19, 20, 21)
- - 2. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, further comprising means for evaluating the voltage drop across said galvanic isolator while in a static state and comparing the result of evaluating said voltage drop to a pre-defined maximum limit.
  - 3. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, further comprising an AC shore power distribution system and means for determining whether the on-shore neutral and hot AC supply conductors of said AC shore power distribution system are reversed.
  - 4. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, further comprising means for detecting both the magnitude and length of time AC current flows in the grounding conductor connecting said galvanic isolator and said earth ground and when said magnitude of time exceeds some predetermined level thereby detecting such excess magnitude or time and responsive thereto by energizing a signaling means.
  - 5. an apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, further comprising means for inducing a momentary AC current into the grounding conductor connecting said galvanic isolator and said earth ground, detecting whether such induced AC current flows to said earth ground and creating a signal responsive to the absence of such flow.
  - 6. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, wherein said first silicon diode reference semi-conductor is one of a first set of said series semi-conductors.
  - 7. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, wherein said second silicon diode reference semi-conductor is one of a second set of said series semi-conductors.
  - 8. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1, wherein said first and second silicon diode reference semi-conductors are placed in parallel with said galvanic isolator.
  - 9. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1 including control means for controlling the sequence of operation of each of said other means.
  - 10. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1 including means for storing said voltage drops thereby enabling said means for comparing and indicating to be operative with respect to said stored voltage drops.
  - 18. An apparatus for applying a series of interrelated electrical tests to AC circuitry associated with a galvanic isolator as claimed in claim 1 including means for storing said voltage drops thereby enabling said means for comparing and determining to be operative with respect to said stored voltage drops.
  - 19. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 1 wherein said AC circuitry comprises a boat'"'"'s on-board electrical system and including:
20. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 18 including:
- a) means for inducing a momentary AC current into said grounding conductor at a first location on said grounding conductor;
  
  b) circuit means at a second location on said grounding conductor closer to said earth ground than said first location for detecting whether such induced AC current flows to said earth ground; and
  
  c) means for creating a signal responsive to the absence of such flow.
21. An apparatus for testing AC circuitry and an associated galvanic isolator as claimed in claim 18 including:
- a) means for inducing an AC current at a location connected to both said galvanic isolator and said earth ground;
  
  b) means for detecting both the magnitude of said induced AC current and length of time said induced AC current flows to said earth ground; and
  
  c) means operative when said magnitude or time exceed some predetermined level for detecting such excess magnitude or time and responsive thereto energizing a signaling means operatively associated therewith.

11. A method for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator having series semi-conductors comprising:
- a) applying a DC voltage of selected first polarity across a first silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  b) applying a DC voltage of said first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  c) comparing the voltage drop across said galvanic isolator with said voltage drop across said first silicon diode reference semi-conductor;
  
  d) applying a DC voltage of selected second polarity opposite said first polarity across a second silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  e) applying a DC voltage of said second polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  f) comparing the voltage drop across said second silicon diode reference semi-conductor with said voltage drop across said galvanic isolator;
  
  g) determining whether the voltage drops across said galvanic isolator and said first silicon diode reference semi-conductor when said DC voltage of said first polarity is applied thereto are each within a predetermined range selected to indicate whether one of the galvanic isolator'"'"'s series semi-conductors is shorted; and
  
  h) determining whether the voltage drops across said galvanic isolator and said second silicon diode reference semi-conductor when said DC voltage of said second polarity is applied thereto are each within a predetermined range selected to indicate whether one of the galvanic isolator'"'"'s series semi-conductors is shorted.
- View Dependent Claims (12, 13, 14)
- - 12. A method for testing a galvanic isolator as claimed in claim 11, further comprising determining whether the voltage drop across said galvanic isolator is sufficiently higher than the voltage drop across said first silicon diode reference semiconductor, to indicate whether or not a first set of galvanic isolator series semi-conductors is operational.
  - 13. A method for testing a galvanic isolator as claimed in claim 11, further comprising determining whether the voltage drop across said galvanic isolator is sufficiently higher than the voltage drop across said second silicon diode reference semi-conductor, to indicate whether a second set of galvanic isolator series semi-conductors is operational.
  - 14. A method for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator as claimed in claim 11 including the step of storing said voltage drops so as to enable said comparing and determining to be made with respect to said stored voltage drops.

15. A method for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator having series semi-conductors comprising:
- a) applying a DC voltage of selected first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  b) if said galvanic isolator is determined by said first step to be neither open circuited or short-circuited, applying a DC voltage of said first polarity across a first silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  c) comparing the voltage drop across said galvanic isolator with the voltage drop across said first silicon diode reference semi-conductor;
  
  d) applying a DC voltage of selected second polarity opposite said first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  e) if said galvanic isolator is determined by said step d) to be neither open circuited or short-circuited, applying a DC voltage of said second polarity opposite said first polarity across a second silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  f) comparing the voltage drop across said galvanic isolator with the voltage drop across said first silicon diode reference semi-conductor;
  
  g) determining whether the voltage drops across said galvanic isolator and said first silicon diode reference semi-conductor when said DC voltage of said first polarity is applied thereto are each within a predetermined range selected to indicate whether one of the galvanic isolator'"'"'s series semi-conductors is shorted; and
  
  h) determining whether the voltage drops across said galvanic isolator and said second silicon diode reference semi-conductor when said DC voltage of said second polarity is applied thereto are each within a predetermined range selected to indicate that one of the galvanic isolator'"'"'s series semi-conductors is shorted.
- View Dependent Claims (16)
- - 16. A method for applying a series of interrelated electrical tests to AC circuitry and an associated galvanic isolator as claimed in claim 15 including the step of storing said voltage drops so as to enable said comparing and determining to be made with respect to said stored voltage drops.

17. An apparatus for applying a series of interrelated electrical tests to AC circuitry associated with a galvanic isolator connected on one side through a grounding conductor to earth ground and having series semi-conductors and being normally operative and arranged to block passage of DC currents in both directions, to permit passage of AC currents in both directions and to permit passage of AC currents through the galvanic isolator to earth ground and which tests include a test for operability of said isolator, said apparatus comprising:
- a) silicon diode reference semi-conductor means electrically accessible for said tests;
  
  b) means for selectively applying to either or both said isolator and silicon diode reference means a DC voltage of either first or second polarity;
  
  c) means for comparing the voltage drops produced by application of said DC voltage to said isolator and silicon diode reference means; and
  
  d) means for determining from such comparison the operability of either or both said AC circuitry and isolator.

22. A method for utilizing a selected number of silicon diode reference semi-conductors for testing selected components of a boat'"'"'s on-board electrical system having an on-board galvanic isolator connected on one side through a grounding conductor to an on-shore earth ground and on an opposite side to a DC ground forming part of a boat'"'"'s on-board electrical system, said galvanic isolator comprising solid state elements normally operative to block passage of DC currents in both directions and to permit passage of AC currents through said galvanic isolator to said earth ground, comprising:
- a) applying a DC voltage of selected polarity across a silicon diode reference semi-conductor and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  b) applying a DC voltage of selected first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  c) comparing the voltage drop across said galvanic isolator when said DC voltage of selected first polarity was applied with the voltage drop across said silicon diode reference semi-conductor;
  
  d) applying a DC voltage of selected second polarity opposite said first polarity across said galvanic isolator and of sufficient magnitude to establish what would be expected to be a normal voltage drop corresponding thereto;
  
  e) comparing the voltage drop across said galvanic isolator when said DC voltage of selected second polarity was applied with said voltage drop across said silicon diode reference semi-conductor; and
  
  f) utilizing indicating means for indicating whether the voltage drops corresponding to application of said DC voltage of first and second polarities across said galvanic isolator and voltage drop corresponding to application of said DC voltage of selected polarity across said silicon diode reference semi-conductor correspond to what would be normally expected.
- View Dependent Claims (23, 24, 25, 26)
- - 23. A method as claimed in claim 22 including the step of storing said voltage drops thereby enabling said comparing and indicating to be made with respect to said stored voltage drops.
  - 24. A method as claimed in claim 22 including the steps of:
25. A method as claimed in claim 22 including the steps of:
- a) inducing a momentary AC current into said grounding conductor at a first location on said grounding conductor;
  
  b) utilizing circuit means at a second location on said grounding conductor closer to said earth ground than said first location for detecting whether such induced AC current flows to said earth ground; and
  
  c) creating a signal responsive to the absence of such flow.
26. A method as claimed in claim 22 including the steps of:
- a) detecting both the magnitude and length of time said AC currents flow to said earth ground; and
  
  b) when said magnitude or time exceed some predetermined level detecting such excess magnitude or time and responsive thereto energizing a signaling means operatively associated therewith.

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Litigation Campaign Assessment

Current Assignee
Keith W. Landreth
Original Assignee
Keith W. Landreth
Inventors
Landreth, Keith W.
Primary Examiner(s)
Metjahic, Safet
Assistant Examiner(s)
KERVEROS, DEMETRIOS C

Application Number

US09/353,324
Time in Patent Office

741 Days
Field of Search

324/537, 324/763, 324/767, 324/71.1, 324/71.2
US Class Current

324/537
CPC Class Codes

G01N 17/02   Electrochemical measuring s...

G01R 31/008   on air- or spacecraft, rail...

G01R 31/50   Testing of electric apparat...

G01R 31/67   Testing the correctness of ...

Electrical integrity test system for boats

First Claim

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Electrical integrity test system for boats

First Claim

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Abstract

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26 Claims

Specification

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