The present invention relates generally to current sensing devices for electrical systems, and more particularly to timed reset fault indicators for alternating current power systems.
Various types of self-powered fault indicators have been constructed for detecting electrical faults in power distribution systems, including clamp-on type fault indicators, which clamp directly over cables in the systems and derive their operating power from inductive and/or capacitive coupling to the monitored conductor; and test point type fault indicators, which are mounted over test points on cables or associated connectors of the systems and derive their operating power from capacitive coupling to the monitored conductor.
Such fault indicators may be either of the manually resetting type, wherein it is necessary that the indicators be physically reset, or of the self-resetting type, wherein the indicators are reset upon restoration of line current. Examples of such fault indicators are found in products manufactured by EGO. Schweitzer Manufacturing Company of Mundelein, Ill., and in U.S. Pat. Nos. 3,676,740, 3,906,477, 4,063,171, 4,234,847, 4,375,617, 4,438,403, 4,456,873, 4,458,198, 4,495,489, 4,974,329, 5,677,678, 6,016,105, 6,133,723 and 6,133,724.
Detection of fault currents in a monitored conductor by a fault indicator is typically accomplished by magnetic switch means, such as a magnetic reed switch, in close proximity to the conductor being monitored. Upon occurrence of an abnormally high fault-associated magnetic field around the conductor, the magnetic switch actuates a trip circuit that produces current flow in a trip winding to position an indicator flag visible from the exterior of the indicator to a trip or fault indicating position. Upon restoration of current in the conductor, a reset circuit is actuated to produce current flow in a reset winding to reposition the target indicator to a reset or non-fault indicating position, or the fault indicator may be manually reset.
Some prior art fault indicators utilize light emitting diodes (LEDs) to display a fault condition. However, activation of LEDs requires a source of power greater than that typically obtainable from inductive or capacitive coupling to a monitored conductor, such as from an internal battery. Even if the LEDs are controlled to flash intermittently, the intermittent current drain from the internal battery is not insubstantial, and replacement of the battery is sometimes required. There is therefore a need to operate the LEDs at reduced current levels especially at nighttime. There is also a need to improve the visibility of the LEDs with visually distinctive patterns, such as by pulse width modulation techniques, to provide a strobe or flicker effect.
There is therefore a need for a battery-powered fault indicator with an energy conservation mode in which there is insubstantial current drain from a high capacity battery, such that the battery may never need replacement. There is also a need for a battery-powered fault indicator with circuitry, including a microprocessor, which places insubstantial current drain on the battery until a fault is detected. There is a further need for such a fault indicator that returns to the energy conservation mode when the fault condition is corrected or when the fault indicator is reset.
In certain other applications, the need arises for a fault indicator that will continue to display a prior fault condition for a predetermined amount of time, such as in the range of one hour to twenty-four hours, rather than self-resetting upon restoration of current in the conductor. Such timed reset fault indicators should be capable of self-resetting after termination of the predetermined time.
Some of these applications also require voltage in-rush restraint and/or current in-rush restraint to prevent false tripping due to voltage and/or current surges, such as when a reclosing relay of a power distribution system closes.
Because of the compact construction and limited power available in self-powered fault indicators, it is preferable that the desired functions of the fault indicator be accomplished with minimal structure and with internal circuitry that has minimal current drain on a high capacity battery. The fault indicator must also provide highly reliable and extended operation over a number of years.
Accordingly, it is a general object of the present invention to provide a new and improved fault indicator with internal circuitry having insubstantial current drain on the battery during non-fault conditions such that the battery may never need replacement during the expected lifetime of the fault indicator.
Another object of the present invention is to provide a fault indicator that is microprocessor-controlled, with the microprocessor operating in a sleep mode during non-fault conditions to conserve battery life.
Yet another object of the present invention is to provide a fault indicator with highly visible LED indicators that are illuminated in distinctive eye-catching patterns, such as with strobe or flicker effects.
A further object of the present invention is to sense the ambient lighting conditions and to reduce the current supplied to the LEDs under lower ambient light levels, such as at night, to further reduce current drain on the battery and to thereby conserve battery life.
Another object of the present invention is to control the amount of power supplied to the indicator LEDs by means of pulse width modulated signals for a predetermined period of time, followed by a longer off time for the LEDs, thereby further conserving battery power.
A still further object of the present invention is to provide a battery-powered fault indicator that functions in a non-fault mode with insubstantial current drain from the battery, and that functions in the fault mode with energy conservation techniques, such that the battery may last the expected lifetime of the fault indicator.
This invention is directed to a fault indicator for indicating the occurrence of a fault current in an electrical conductor. The fault indicator has a housing, a high capacity battery, a plurality of light emitting diodes (LEDs) visible from the exterior of the fault indicator upon the occurrence of a fault, and electronic circuitry for sensing a fault, for actuating the LEDs to indicate a fault and for automatically resetting the LEDs to a non-fault indicating condition a predetermined time after the fault has occurred. The electronic circuitry, including a microprocessor that operates in a sleep mode during non-fault conditions, conserves energy by drawing insubstantial current from the high capacity battery during non-fault conditions such that the battery may never need replacement during the expected lifetime of the fault indicator. A light sensor senses the ambient lighting conditions and the microprocessor reduces current supplied to the LEDs under reduced light levels, such as night, to further reduce current drain on the battery and to conserve battery life. Preferably, the microprocessor controls activation of the fault indicating LEDs with pulse width modulated (PWM) signals during defined time intervals for improved visibility. Visibility is further improved where the PWM signals for the indicator LEDs are interleaved in time to provide a highly distinctive flicker effect. Alternately, if the PWM signal for one LED quickly follows the PWM signal for the other LED, a highly distinctive strobe effect is provided by the LED indicators.
The features of the present invention which are believed to be novel are set forth with particularity in the appended claims. The invention, together with the further objects and advantages thereof, may best be understood by reference to the following description taken in conjunction with the accompanying drawings, in the several figures in which like reference numerals identify like elements, and in which:
Referring to the Figures, and particularly
Circuit module 22 includes a housing 30 (
Housing 30 and end cap 53 may be formed from any suitable material, such as plastic. End cap 53 forms part of the housing 30, and may be sonically welded to housing 30 to seal the interior of fault indicator 20 against contamination. A battery holder 28 within housing 30 includes a removable end cap 29, which provides access to a cylindrical battery compartment within which a battery 38 (
Circuit module 22 also includes status indicators in the form a pair of LEDs 34 and 35 to indicate whether a fault has occurred on cable 21. In operation, during normal current flow through conductor 21, LEDs 34 and 35 are normally off and not illuminated. Upon occurrence of a fault in a monitored conductor, LEDs 34 and 35 are illuminated by electronic circuitry, which is discussed in further detail below. For best viewing from different angles of view, LEDs 34 and 35 are at least flush with the exterior surface of end cap 53, and may project slightly above the top surface 40 of the end cap, or end cap 53 may be provided with convex lenses 43 to provide illumination in about a 180 degree field of view for better viewing by service personnel. LEDs 34 and 35 may be selected from any color commercially available. However, a color commonly associated with a fault, such as red, is preferred.
A light sensor 173 may be disposed on the face 40 of fault indicator 20 to sense ambient light levels. As further discussed below, light sensor 173 may influence the intensity of light provided by LEDs 34 and 35 under differing ambient light conditions.
A pigtail 192 may provide signals relating to the operational status of fault indicator 20, such as to a remote location, for remotely monitoring an electrical distribution system or for automation purposes.
With reference to
A third LED 37 is disposed internally in housing 30, such as in the potting compound 39 that encases most of the electronic circuitry. Third LED 37 becomes illuminated during a fault condition when the light sensor 44 also senses a low ambient lighting level, such as that at nighttime. The objective is to make housing 30 glow in the dark after a sensed fault condition for better visibility. To this end, potting compound 39 is preferably clear and housing 30 is preferably formed from translucent plastic. Of course, other combinations of materials may be selected to achieve similar results, such as translucent potting compound 39 with a clear or translucent housing 30. When third LED 37 is illuminated after sensing a fault condition at reduced ambient light levels, LEDs 34 and 35 are also preferably illuminated to indicate the fault condition at the face 40 of fault indicator 20.
In order to better understand some of the aspects of the present invention, the application of fault indicators 20 and 20a (hereinafter collectively referred to as fault indicator 20 unless otherwise noted) in an electrical distribution system will now be considered. Turning now to
In the example of
Reclosing relays, such as relay 61, attempt to restore power to the distribution system 60 after a predetermined time, such as about 240 milliseconds (ms). Relay 61 may close for about 300 ms, and if the fault persists, relay 61 will again reopen for another 240 ms. If the fault remains after about three reclosing attempts, the relay 61 will remain in an open or locked out condition. In the example of
However, if fault indicators 70–73 are of the type that automatically reset upon the restoration of line current, fault indicators 70–73 will be reset before a lineman can view these fault indicators. Thus, fault indicators 70–73 will not assist in quickly isolating the fault on the system 60. Instead, the lineman will have to try to find tripped fault indicator 81 and/or blown fuse 89. It will of course be appreciated that the fault indicators 70–83 are positioned at physically disparate locations on the lines 62–69 of the system 60 such that individual review of each fault indicator may be time consuming and inefficient.
Fault indicator 20 has a timed reset to reset some hours after a fault occurs. Thus, in the example of
Rather than waiting for the predetermined reset time to elapse, fault indicator 20 may be manually reset at any time. To this end, a reset magnetic reed switch 120 is disposed in the housing 30 or 30a in
Turning now to
Substrate 148 with the electrodes 146 and 147 thereon may be fabricated by any suitable means, including printed circuit board techniques, deposition of metal on a ceramic substrate or by physically adhering metal foil onto a phenolic base. For example, the electrodes 146 and 147 may be a copper-nickel alloy foil about 10 to 12 thousandths of an inch (0.25 to 0.30 mm) thick. Metallic plate 50 is preferably provided with one or more apertures, such as 149 and 150 for good flow of a potting compound in and about the electrostatic assembly. For example, a urethane-based potting compound may be used, such as that commercially available under the BIWAX brand from the Biwax Corporation of Des Plaines, Ill. BIWAX is a registered trademark owned by the Biwax Corporation.
With reference to
As seen in
Illustrated in
Electrostatic assembly 145 in
Returning now to
The electronic circuitry 100 for fault indicator 20 is shown in greater detail in the schematic diagram of
However, if a voltage inrush condition is sensed, some energy is transferred from capacitor 116 to capacitor 119, which positively biases the gate to source of FET 118. FET 118 then becomes conductive and quickly discharges capacitor 114 through resistor 122 to ground, as well as sinking any current continuing to be rectified by diode bridge 112. Capacitor 116 discharges much more slowly through resistor 117, keeping FET 118 in conduction. Line 123 to gate 127 is then kept at a logic low level.
This voltage inrush restraint circuit is effective for a wide range of applications. For example, this restraint circuit will perform effectively in a wide range of applications from 69 kilovolt lines down to 2.4 kilovolt lines.
The current sensing circuitry in
As previously described, the other input to NAND gate 127 on line 123 will also be at a logic high if there is no voltage inrush. Thus, output line 142 will be at a logic low and the output of NAND gate 128 to terminal 11 of microprocessor 105 will be at a logic high. In summary, terminal 11 of microprocessor 105 is normally at a logic low. However, if magnetic reed switch 45 closes upon sensing a fault and the inrush restraint circuit is in its normal operation with no voltage inrush, terminal 11 will switch from a logic low level to a logic high level to indicate the occurrence of a fault. This change of signal at terminal 11 will cause microprocessor 105 to come out of a sleep mode.
Microprocessor 105 is normally in a sleep state in which it draws virtually no power from battery 38 or 38a. For example, circuitry 100, including microprocessor 105, may typically draw 10 microamperes, or less, from battery 38 or 38a when microprocessor 105 is in the sleep mode. Sleep states or modes are sometimes also referred to as a power down mode. This sleep state is represented by block 161 in the microprocessor flow chart in
A photo sensor 173 (
Microprocessor 105 then decides whether to operate LEDs 34 and 35 in the low current mode of nighttime, block 167, or in the high current mode of daytime, block 168. For example, microprocessor 105 may briefly sample the ambient lighting conditions about once every 15 to 30 minutes. Indicator LEDs 34 and 35 may be operated at lower illumination intensity during lower illumination levels to further conserve battery power. For example, LEDs 34 and 35 may be supplied with a higher level of current of about 15 to 20 mA during daytime, as represented by the peak waveform 193 in
In accordance with one aspect of the present invention, LEDs 34 and 35 are preferably not simultaneously turned on and off by microprocessor 105. However, if desired, LEDs 34 and 35 could overlap when on, or even have simultaneous on times and still provide a distinctive characteristic. Instead, as shown in
Note also that LED 35 does not turn on until LED 34 is off to preferably provide an interleaved PWM energization characteristic for LEDs 34 and 35. Since LED 34 is off for 100 ms and the duration of LED 35 is 80 ms in the on mode, the timing relationship between the on and off modes can be changed. For example, LED 35 might not turn on until 10 ms after LED 34 is off such that LED 35 is illuminated during the middle of the off time for LED 34. Of course, if LED 35 is not illuminated until 20 ms after LED 34 turns off, the falling edge of the LED 34 waveform will be at the rising edge of the LED 35 waveform. With the waveforms of LEDs 34 and 35 displaced in time or alternating in time, as shown in
In the example of
With reference to the schematic diagram in
To further save on battery current drain, LEDs 34 and 35 are preferably not continuously illuminated in either the daytime or nighttime modes. Instead, as shown in
The previously described nighttime LED 37 disposed in the interior of housing 30 or 30a may be actuated by biasing FET 179 into its conductive state when microprocessor 105 determines from photo sensor 173 that there is low ambient lighting to give housing 30 a glowing effect if LED 37 is continuously powered. However, if LED 37 is intermittently powered, as described above for LEDs 34 and 35, and in the timing diagrams of
A connector 191 has a plurality of conductors to microprocessor 105 and to other portions of circuitry 100 to enable programming of microprocessor 105.
As explained above in connection with
A reset switch 120 has an input to terminal 10 of microprocessor 105 for manually resetting the fault indicator with a magnetic tool at any time. If fault indicator 20 is manually reset, any LEDs 34, 35 and 37 will be deactivated and microprocessor 105 will return to its sleep mode. Microprocessor 105 is commercially available from Texas Instruments of Dallas, Tex. under part number MSP430F1232. Other commonly available microprocessors or microcontrollers may be used in place of this microprocessor.
Due to the typical outdoor environmental conditions that the fault indicators 20 are subjected to when installed on the conductors of a power distribution system, 10 years is about the expected lifetime of these fault indicators. Advances in the state of the technology can also be expected to obsolete fault indicators in about 10 years. Thus, the low current drain of circuitry 100 in combination with the high capacity of battery 38a provides a fault indicator 20 in which the battery can be realistically expected to last the lifetime of the fault indicator, without any needed or required replacement of the battery during the fault indicator's operative lifetime.
While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made therein without departing from the invention in its broader aspects.
This patent application is a non-provisional application of U.S. provisional patent application Ser. No. 60/339,256 filed on Oct. 26, 2001. This patent application is also related to the following non-provisional patent applications filed concurrently herewith: Microprocessor Controlled Fault Indicator with Battery Conservation Mode, U.S. application Ser. No. 10/280,322 Microprocessor Fault Indicator Having LED Fault Indication Circuit with Battery Conservation Mode, U.S. application Ser. No. 10/280,219; Microprocessor Controlled Fault Indicator Having Inrush Restraint Circuit, U.S. application Ser. No. 10/280,329; Microprocessor Controlled Directional Fault Indicator, U.S. application Ser. No. 10/280,195; and Microprocessor Controlled Fault Indicator with Circuit Overload Condition Detection, U.S. application Ser. No. 10/280,328 all filed on Oct. 25, 2002, and all incorporated by reference herein, in their entireties.
Number | Name | Date | Kind |
---|---|---|---|
3676740 | Schweitzer, Jr. | Jul 1972 | A |
3906477 | Schweitzer, Jr. | Sep 1975 | A |
4063171 | Schweitzer, Jr. | Dec 1977 | A |
4234847 | Schweitzer, Jr. | Nov 1980 | A |
4438403 | Schweitzer, Jr. | Mar 1984 | A |
4495489 | Schweitzer, Jr. | Jan 1985 | A |
5402071 | Bastard et al. | Mar 1995 | A |
5959537 | Banting et al. | Sep 1999 | A |
6016105 | Schweitzer, Jr. | Jan 2000 | A |
6133723 | Feight | Oct 2000 | A |
6133724 | Schweitzer et al. | Oct 2000 | A |
6734662 | Fenske | May 2004 | B1 |
Number | Date | Country | |
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60339256 | Oct 2001 | US |