High impedance fault location in DC distribution systems

What is claimed is: 1. A method of locating a high impedance fault in a DC power distribution system, the method comprising: operating a plurality of measurement devices operatively coupled to the DC power distribution system; operating a DC power distribution system controller operatively coupled to the plurality of measurement devices; identifying, with the DC power distribution system controller, a fault condition of the DC power distribution system; measuring, with the plurality of measurement devices, a forward fault current flowing in a first portion of the DC power distribution system from a first node to the fault, a reverse fault current flowing in a second portion of the DC power distribution system from a second node to the fault, and a voltage across the first portion of the DC power distribution system at the first node; determining, with the DC power distribution system controller, an inductance of the first portion of the DC power distribution system, a resistance of the first portion of the DC power distribution system, and a resistance of the fault using the forward fault current, the reverse fault current and the voltage; and identifying, with the DC power distribution system controller, a physical location of the fault in the DC power distribution system using at least one of the inductance of the first portion and the resistance of the first portion. 2. The method of claim 1 wherein the act of measuring comprises making a plurality of measurements comprising at least three measurements of forward fault current, reverse fault current and voltage across the first portion, and wherein the plurality of measurements is used in determining the inductance of the first portion, the resistance of the first portion, and the resistance of the fault. 3. The method of claim 2 wherein the act of determining comprises determining a matrix A using the at least three measurements of forward fault current and reverse fault current, determining an array B using the least three measurements of voltage across the first portion, and determining an array C including the inductance of the first portion, the resistance of the first portion, and the resistance of the fault using the matrix A and the array B. 4. The method of claim 3 wherein the array C is determined by calculating C =( A T A ) −1 A T B. 5. The method of claim 1 wherein the act of identifying a physical location utilizes a predetermined relationship between the physical location and one of the inductance of the first portion or the resistance of the first portion. 6. The method of claim 5 wherein the predetermined relationship comprises one of a line resistance per unit distance and a line inductance per unit distance. 7. The method of claim 1 wherein the reverse fault current is determined using currents in a plurality of branches of the second portion of the DC power distribution system. 8. A DC power distribution system comprising: a DC power distribution network; a plurality of measurement devices operatively coupled to the DC power distribution network at a plurality of spaced apart locations; an electronic control system structured to execute program instructions stored in a non-transitory memory medium during a high impedance fault condition of the DC power distribution system to: receive a plurality of first measurements from a first one of the measurement devices, each of the first measurements comprising a voltage measurement and a forward fault current measurement, receive a plurality of second measurements from a second one of the measurement devices, each of the second measurements comprising a reverse current measurement, determine an inductance of a first portion of the DC power distribution system extending between the first measurement device and the high impedance fault, a resistance of the first portion of the DC power distribution system, and a resistance of the fault using the plurality of first measurements and the plurality of second measurements, and identify a physical location of the fault in the DC power distribution system using at least one of the inductance of the first portion and the resistance of the first portion. 9. The system of claim 8 wherein the plurality of measurement devices comprise smart circuit breakers. 10. The system of claim 8 wherein the plurality of measurement devices comprise sensors positioned proximate respective protective devices. 11. The system of claim 8 wherein the forward fault current measurement and the reverse fault current measurement comprise direct measurements of current, and a time rate of change of the forward fault current is calculated from a plurality of forward fault current measurements. 12. The system of claim 8 wherein the measurement devices are configured to perform their respective plurality of measurements at a sampling rate selected using at least one of a fault transient time constant and a measurement signal noise value. 13. The system of claim 8 wherein least squares regression is used to calculate the inductance of the first portion of the DC power distribution system, a resistance of the first portion of the DC power distribution system, and a resistance of the fault. 14. The system of claim 8 wherein the first measuring device and the second measuring device comprise smart circuit breakers structured to controllably interrupt current through a portion of the coupled power distribution line. 15. The system of claim 14 wherein the electronic control system is structured to transmit a trip signal to at least one of the smart circuit breakers in response to determining that the location of the fault is within the protection zone of the smart circuit breaker. 16. A DC power distribution system comprising: at least one DC power distribution line; at least two power sources coupled to the DC power distribution line and structured to provide DC power to the DC power distribution line; at least two smart circuit breakers operatively coupled to the DC power distribution line between the two power sources, each of the smart circuit breakers structured to sense one or more electrical characteristics associated with the DC power distribution line and to controllably interrupt current through the DC power distribution line; and a control system structured to determine the location of a high impedance fault between two of the smart circuit breakers devices using one or more electrical characteristics sensed by each of the two smart circuit breakers to calculate inductance and resistance of a portion of the DC power distribution line between one of the smart circuit breakers and the high impedance fault. 17. The system of claim 16 wherein the control system is structured to calculate the impedance of the DC power distribution line between one of the smart circuit breakers and the high impedance fault by performing linear regression analysis using a plurality of samples of electrical characteristics sensed by the two smart circuit breakers. 18. The system of claim 17 wherein the one or more electrical characteristics sensed by the two smart circuit breakers comprise at least one of voltage measurement and current measurement. 19. The system of claim 17 wherein the samples of electrical characteristics are sensed by the two smart circuit breakers in response to determining a fault has occurred within the DC power distribution line. 20. The system of claim 19 wherein the control system is structured to request the samples from the two smart circu