(19)
(11)EP 1 464 973 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
01.07.2015 Bulletin 2015/27

(21)Application number: 04251895.1

(22)Date of filing:  30.03.2004
(51)International Patent Classification (IPC): 
G01R 31/333(2006.01)

(54)

Methods and apparatus for analyzing high voltage circuit breakers

Verfahren und Vorrichtung zur Analyse von Hochspannungsschaltgeräten

Méthode et appareil pour l'analyse d'interrupteurs de puissance à haute tension


(84)Designated Contracting States:
DE ES FR GB IT SE

(30)Priority: 31.03.2003 US 403695

(43)Date of publication of application:
06.10.2004 Bulletin 2004/41

(73)Proprietor: Megger Sweden AB
182 17 Danderyd (SE)

(72)Inventor:
  • Stanisic, Zoran
    18773 Taby (SE)

(74)Representative: Estreen, Lars J.F. 
Bergenstråhle & Lindvall AB P.O. Box 17704
118 93 Stockholm
118 93 Stockholm (SE)


(56)References cited: : 
CH-A- 89 137
GB-A- 788 548
US-A- 3 612 985
DE-A1- 3 837 605
JP-A- H0 359 471
US-A- 5 119 260
  
  • PATENT ABSTRACTS OF JAPAN vol. 1996, no. 02, 29 February 1996 (1996-02-29) & JP 7 280897 A (NISSIN ELECTRIC CO LTD), 27 October 1995 (1995-10-27)
  
Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


Description


[0001] This invention relates generally to high voltage circuit breakers, and more specifically to methods and systems for analyzing circuit breaker contacts.

[0002] During testing of at least some known circuit breakers, a plurality of circuit breaker parameters may be monitored to facilitate determining that the circuit breaker is operating as designed. One such parameter may be a circuit breaker contact pair status, which may indicate whether the contacts are opened or closed, and an analog position of the circuit breaker contacts.

[0003] Timing the main contact and auxiliary contacts may also be indicative of each contacts' state. At least some known contacts are timed using a small DC current induced into a first of the pair of contacts and detecting the current at a second of the contact pair. In one embodiment, the DC current may be recorded such that a current trace may be used to determine the timing of each contact. In an alternative embodiment, the presence or absence of the DC current may be used to start and stop timers to facilitate directly measuring the contact timing. Circuit breaker contact analog position and contact motion may be determined applying a mechanical transducer to the circuit breaker contact mechanism to transfer a motive force to a movable contact of the contact pair.

[0004] Circuit breaker contact timing may be affected by induced currents, voltages, or other disturbances in a high voltage environment where circuit breaker typically is performed. Such disturbances may put a demand on the test equipment that limit the effectiveness and/or portability of the test equipment. Motion measurement may be complicated by mechanical difficulties when mounting the transducer to the circuit breaker and when measuring rapid mechanical acceleration during circuit breaker operation. Additionally, a material the circuit breaker contact is constructed from may adversely affect the timing result. At least some known circuit breaker designs use contact materials with a relatively higher contact resistance, such as, for example, graphite, to protect the contact surface from wear during contact arcing.

[0005] Furthermore, present timing techniques require removal of grounding cables from the circuit breaker under test to receive accurate results.

[0006] US patent publication US 5,119,260 describes a method of measuring the delay times of a circuit breaker during normal operation. A test signal is applied to the contacts of a circuit-breaker and the capacitance changes during operation are detected.

[0007] Patent publication JP 03-059471 discloses a method relating to a circuit-breaker, whereby a test signal source injects a test signal to ground and to a circuit-breaker contact.

[0008] According to the invention, a method for analyzing circuit breakers is provided as defined in appended claim 1.

[0009] The invention will now be described in greater detail, by way of example, with reference to the drawings, in which:-

Figure 1 is a schematic illustration of an exemplary high voltage circuit breaker phase;

Figure 2 is a schematic illustration of an exemplary equivalent circuit of a contact pair that may be used in the circuit breaker phase shown in Figure 1;

Figure 3 is a schematic illustration of an exemplary testing circuit that may be used to test a circuit breaker that is represented by the equivalent circuit shown in Figure 2;

Figure 4 is a schematic illustration of an equivalent circuit of the testing circuit shown in Figure 3, illustrated at the time of first contact touch; and

Figure 5 is a schematic illustration of an exemplary testing circuit that may be used to time the contacts of the circuit breaker phase shown in Figure 1;

Figure 6 is a graph of an exemplary trace of the output voltage of the testing circuit during a test procedure; and

Figure 7 is a flow diagram of an exemplary method 700 of measuring timing of a circuit breaker while grounding each circuit breaker contact.



[0010] Periodic testing of circuit breakers may include a contact timing test. The timing test continuously measures the circuit breaker contact capacitance, from which the moment of first contact touch, and when the maximum capacitance between the contacts is reached may be determined. Further, the maximum capacitance value, in the function of time, may be used as a start or a stop value in the total operating time measurement.

[0011] Additionally, although the herein described methods are described with regard to circuit breaker contacts, it is contemplated that the benefits of the invention accrue to non-circuit breaker contacts such as those contacts typically employed in, for example, but not limited to, relays or switches.

[0012] Figure 1 is a schematic illustration of an exemplary high voltage circuit breaker phase 100. A high voltage circuit breaker (not shown) may include a pre-insertion resistor 102 and a moving resistor contact 104 electrically in parallel with a moving main contact 106. In the exemplary embodiment, phase 100 includes two breaks 108 each break 108 includes a pre-insertion resistor (only one shown in Figure 1).

[0013] In operation, from an open position, the circuit breaker receives a command to close, linkages within the circuit breaker cause movable portions of contacts 104 and 106 to move toward engagement of the respective non-movable portions of contacts 104 and 106. During a testing sequence, movement of the movable portion of contacts 104 and 106 may begin a timer. In the exemplary embodiment, the movement of the movable portion of contacts 104 and 106 is detected using electrical parameters associated with contacts 104 and 106. After a predetermined distance of travel of the movable portions of contacts 104 and 106, the movable portion of pre-insertion resistor contact 104 engages a respective non-movable portion. After a predetermined time delay, the movable portion of contact 106 engages a respective non-movable portion of main contact 106. During testing, the timing of circuit breaker contacts 104 and 106 may be determined. In an embodiment wherein there is no pre-insertion resistor 102 only the timing of main contact 106 and auxiliary contacts (not shown) are determined.

[0014] Figure 2 is a schematic illustration of an exemplary equivalent circuit 200 of a contact pair that may be used in circuit breaker phase 100 (shown in Figure 1). Equivalent circuit 200 includes a capacitor 202 that represents contact surfaces of circuit breaker contacts 104 and 106. During testing, capacitance parameters associated with the circuit breaker contacts, such as, a surface area of each contact surface and a dielectric media surrounding the contact pair each have a constant value. A distance between the contact surfaces of the contact pair is variable based on the contact state, opened or closed, and a amount of travel between fully opened and fully closed. The distance between the contact surfaces is the only capacitance parameter associated with the circuit breaker contacts that substantially varies during operation of the circuit breaker.

[0015] A first lead 204 of capacitor 202 is electrically coupled to a first lead 206 of a resistor (Ra) 208 and a second lead 210 of resistor (Ra) 208 is electrically coupled to a first lead 212 of an inductor (La)214. A second lead 216 of inductor (La) 214 is coupled to a forcing function (not shown) that represents a test signal used to measure the circuit breaker contact timing. Resistor (Ra) 208 and inductor (La) 214 represent the inductance and resistance of the circuit breaker input components. A second lead 218 of capacitor 202 is electrically coupled to a first lead 220 of a resistor (Rb) 222 and a second lead 224 of resistor (Rb) 222 is electrically coupled to a first lead 226 of an inductor (Lb) 228. A second lead of inductor (Lb) 228 is coupled to the forcing function return. Resistor (Rb) 222 and inductor (Lb) 228 represent the inductance and resistance of the circuit breaker output components. Resistors (Ra) 208 and (Rb) 222, and inductors (La) 214 and (Lb) 228 are represented as constant resistance and inductance values, respectively. Circuit parameters affecting these model components, such as, cable length, diameter and material are substantially constant during testing. The absolute values of resistors (Ra) 208 and (Rb) 222, and inductors (La) 214 and (Lb) 228 and the steady state value of the contact capacitance are determined by the physical characteristics of each circuit breaker and may vary depending on location and environmental conditions.

[0016] During testing, equivalent circuit 200 models the high voltage circuit breaker as a dynamic system with one static and one moveable contact, represented by capacitor 202 that changes capacitance value by the motion of the moveable electrode. By measuring the capacitance dynamically, a minimum distance between circuit breaker contacts before the first contact touch, which corresponds to maximum capacitance in the system may be determined. Additionally, the occurrence of the maximum capacitance value may be used to start and/or stop one or more timers measuring a total operating time (timing) and a recorded capacitance waveform enables analyzing other circuit breaker parameters such as, but not limited to contact motion and interrupting media.

[0017] Figure 3 is a schematic illustration of an exemplary testing circuit 300 that may be used to test a circuit breaker that is represented by equivalent circuit 200 (shown in Figure 2). Circuit 300 includes a test source that is used to generate a high frequency sine wave signal (Vg(t)) through the circuit breaker contact being measured as represented by circuit 200. In the exemplary embodiment, a frequency is considered to be a high frequency if the frequency is greater than about ten kilohertz. In an alternative embodiment, a frequency is considered to be a high frequency if the frequency is greater than about one kilohertz. A filter 304 is coupled in electrical series to the output of circuit 200. Filter 304 includes a resistor 306, a capacitor 308, and an inductor 310 electrically coupled in parallel to filter noise. In the exemplary embodiment, values of resistance, capacitance and inductance for each respective component in filter 304 is pre-selected to make filter 304 resonant at a frequency that is equal to the frequency of source 302. In an alternative embodiment, the frequency of source 302 is adjusted to a resonant frequency of filter 304. An output voltage (Vout(t)) 312 of circuit 300 is taken across filter 304. In the exemplary embodiment, output voltage 312 is electrically coupled to a microprocessor 314, which is programmed to receive output voltage 312, analyze data contained within output voltage 312, control voltage source 302, receive commands from an operator, execute scripts that include automatic testing procedures, and generate testing data output. Microprocessor 314 is programmed to analyze output voltage 312 to derive other circuit breaker characteristics indirectly, such as, but not limited to pressure in a contact chamber of the circuit breaker, changes in dielectric constant of gas within the chamber, circuit breaker actuating spring elasticity constant, acceleration of circuit breaker components during operation, vibration of circuit breaker component parts, and an operating time of the circuit breaker.

[0018] During testing, with the breaker contacts in an open state, source 302 injects a high frequency sine wave signal into the circuit breaker. Output 312 receives a signal that corresponds to circuit 200 with a minimum capacitance value for capacitor 202. The minimum capacitance value occurs when circuit breaker contacts represented by capacitor 202 are open. The circuit breaker is commanded to close and the movable contact begins moving toward the non-movable contact. As the movable contact travels closer to the non-movable contact, the capacitance of capacitor 202 increases proportionally to the distance traveled. The maximum capacitance value occurs just prior to the time when the movable contact electrically touches the non-movable contact. The maximum capacitance value of circuit 200 corresponds to a maximum value of output voltage 312. The maximum value of output voltage 312 may be obtained by differentiating the output voltage function Vout(t) with respect to time and setting the equation to be equal to zero. Mathematically the equation is:



[0019] Than, by equating result to zero, capacitance C is given by:



[0020] Where L = La + Lb and R = Ra + Rb

[0021] The output voltage 312 is electrically coupled to a circuit breaker test device (not shown) that includes a microprocessor for controlling test scripts, computing results from input data, analyzing data received, and generating output displays and printed reports. The term microprocessor, as used herein, refers to microprocessors, microcontrollers, reduced instruction set circuits (RISC), application specific integrated circuits (ASIC), logic circuits, and any other circuit or processor capable of executing the functions described herein. In the exemplary embodiment, testing circuit 300 is a subcircuit of the testing device positioned within testing device 300. In an alternative embodiment, testing circuit 300 is a separate component electrically coupleable to testing device 300, and also configurable to electrically couple to an alternate testing device (not shown).

[0022] By using a high frequency test voltage with resonant filtering of the output voltage the circuit breaker contact position may be measured dynamically by measuring the capacitance between the fixed and the moving contacts of the circuit breaker. By measuring the maximum capacitance value, the minimum distance between electrodes may be determined.

[0023] Figure 4 is a schematic illustration of an equivalent circuit 400 of testing circuit 300 (shown in Figure 3) illustrated at the time of first contact touch. At the time when the movable contact first comes into electrical contact with the non-movable contact, capacitor 202 may be represented as a short circuit 402 and output 312 Vout(t) is no longer a monotone function, but becomes a step function with ΔVout as the step value. The time occurrence of the voltage step corresponds to the time the circuit breaker contacts close. This time value may be recorded for use in calculations and may be used to start and stop circuit breaker operational timers. Similarly, during an opening testing sequence, when the circuit breaker contacts first open ΔVout will be a negative step function

[0024] The capacitance based contact timing circuit may facilitate measuring parameters of high voltage circuit breakers contact systems, such as, but not limited to a start event of the contact geometrical position from the circuit breaker electrically isolated open position, the movement of linear travel of the movable contact, the first electrical touch of each contact, and the penetration as a function of dynamic resistance from the first contact touch to a geometrical end position.

[0025] The circuit also facilitates evaluating data from a synchronized time base to comply with standards and calculating circuit breaker parameters and enabling analysis of circuit breaker operation, such as, but not limited to, measuring actual linear movement of each movable contact, measuring a time elapsed from a synchronized start to first touch or last separation of each movable contact, measure a time elapsed from a start event, such as, the contact geometrical position from the circuit breaker electrically isolated open position, to a contact first touch, or a last separation of each contact to an isolated open position, determine a contact velocity in a function of time and movement within above positions, determine overlap, wherein a movement and time elapsed from each contact separation to arcing contact separation at open an operation is measured, and determine a quality of each contact interrupting medium.

[0026] Figure 5 is a schematic illustration of an exemplary testing circuit 500 according to the invention that may be used to time the contacts of circuit breaker phase 100 (shown in Figure 1). During testing, source 302 injects a test signal into circuit breaker contact 106 within break 108. If contact 106 is in an open state, the test signal is transmitting capacitively through contact 106 to the input of resonant filter 304. The filtered output of filter 304 is transmitted to rectifier 502 and low-pass filter 504. The combination of rectifier 502 and low-pass filter 504 envelopes the output of filter 304 to facilitate reducing high frequency noise and facilitate reducing unwanted non-peak related signal information. In the exemplary embodiment, a corner frequency 1/5 of the resonant frequency of capacitor 308 and inductor 310 is used. The signal value from filter 504 is then compared with the voltage value that is greater than RoVg(t)peak/(Ra+Rb+Ro) by comparator 506. The output signal from comparator 506 is equal to ΔVout and is transmitted to a digital input of microprocessor 314 as the "make" or "break" timing result. The output of filter 504 is also transmitted to an input of amplifier 508 to provide an analog output signal to microprocessor 314 for further processing. Inductors 510 and 512 are electrically coupled in series with grounding cables 514 and 516, respectively to drain any currents induced into the circuit breaker circuit. Grounding cables 514 and 516 are applied to the circuit breaker to ensure the personnel safety of operating personnel during testing of the circuit breaker. By introducing an inductance:

into the circuit breaker grounding cables 514 and 516, the circuit breaker timing measurement may be conducted without disconnecting grounding cables 514 and 516 from the circuit breaker thereby providing greater safety protection to operating personnel.

[0027] Figure 6 is a graph 600 of an exemplary trace 602 of output voltage 312 of testing circuit 300. Graph 600 includes an x-axis 604 indicative of time, and a y-axis 606 that illustrates a magnitude of output voltage 312 at each corresponding unit of time. At t(0) 608, a circuit breaker operating signal is triggered. Between time, t(0) 608 and a time t(1) 610 the circuit breaker movable contact is moving towards the circuit breaker non-movable contact. As the contacts move closer together, the capacitance and hence, the voltage across the contacts increases. The impedance of the contacts may be determined from the equation: Z= Ra+Rb+ω(La+Lb)+(1/ωC). At time t(1) 610, a first contact is detected by the step jump in Vout at point 612. At point 612 a "make" signal is generated based on the detected step jump. During jump 614, a dynamic resistance (Z) between the circuit breaker contacts in motion, termed the penetration process, may be determined based on the equation. Z=Ra+Rb+ω(La+Lb). At a point 616, the dominant impedance on the system becomes the inductance of the circuit breaker cables and may be determined by the equation Z=ω(La+Lb).

[0028] Figure 7 is a flow diagram of an exemplary method 700 for analyzing a circuit breaker. Method 700 includes electrically coupling 701 each circuit breaker contact to ground. A first grounding cable may be coupled to a line side contact of the circuit breaker to a local ground connection. In one embodiment, a inductance of about one microhenry is coupled in series with the grounding cable. In an alternative embodiment, an inductance of less than about one millihenry is coupled in series with the grounding cable. Similarly, a second grounding cable may be electrically coupled to a load side of contact of the circuit breaker to a local ground connection. Inductance may be coupled in series with the grounding cable as described above. A test voltage is applied across the circuit breaker contact pair. In the exemplary embodiment, the test voltage is a high frequency sine wave signal. The frequency of the test signal is selected to match the resonant frequency of the circuit breaker contact and filter circuit, which are electrically coupled in series with the source. Alternatively, impedance values of the components of the filter circuit may be selected such that the resonant frequency of the filter matches the output frequency of the test source. During testing, the output voltage taken across the filter circuit is proportional to a capacitance value of the circuit breaker contact. Accordingly, measuring 704 an output voltage of the testing circuit provides indication of the capacitance of the circuit breaker contact. The gap defined between each contact determines the capacitance of the circuit breaker contact. The state of the circuit breaker contact is changed 706 from an open position to a closed position or the closed position to the open position by automatic action taken by a microprocessor executing within the test device or by a manual command initiated by an operator. As the movable contact of the circuit breaker contact pair moves relative to the non-movable contact, the capacitance between the contacts changes proportionally with respect to the distance separating the contacts. As the contacts engage the testing circuit configuration changes such that the output voltage changes by a step amount. The step change is detected 708 in the output voltage that corresponds to the change of state of the circuit breaker. An output signal at the time of the step change is generated for use in analyzing a condition of the circuit breaker contacts and dielectric medium.

[0029] While the present invention is described with reference to measuring timing and resistance of contacts of a high voltage circuit breaker, numerous other applications are contemplated. For example, it is contemplated that the present invention may be applied to any system wherein electromagnetic interference may induce currents into measured parameters and measuring devices such that the accuracy of such measurements is reduced without suppression of the induced currents.

[0030] The above-described high voltage circuit breaker testing system is cost-effective and highly reliable for determining a circuit breaker contact timing and resistance in the presence of induced currents from electromagnetic interference. More specifically, the methods and systems described herein facilitate determining circuit breaker operating times and contact resistances accurately in the presence of electromagnetic induced currents in the circuit breaker circuit and testing circuit. In addition, the above-described methods and systems facilitate providing an accurate and repeatable circuit breaker timing and contact resistance measurement with minimal operator interaction. As a result, the methods and systems described herein facilitate maintaining high voltage circuit breakers in a cost-effective and reliable manner.

[0031] Exemplary embodiments of circuit breaker testing systems are described above in detail. The systems are not limited to the specific embodiments described herein, but rather, components of each system may be utilized independently and separately from other components described herein. Each system component can also be used in combination with other system components.


Claims

1. A method (700) for analyzing a circuit breaker (100) that includes at least one contact pair (106) that includes at least one movable contact (106), said method comprising:

a. applying a test voltage across a circuit breaker contact pair comprising applying the test voltage from a circuit breaker testing device (300) electrically coupled across the circuit breaker contact;

b. measuring (704) an output voltage signal that is proportional to a capacitance of the circuit breaker contact pair, wherein measuring the output voltage comprises measuring the output voltage across a filter circuit (304);

c. changing a state (706) of the circuit breaker contact pair from at least one of an open position to a closed position and the closed position to the open position; and

d. detecting (708) a step change of the output voltage (312) that corresponds to the change of state of the circuit breaker, wherein

e. the step of applying a voltage across the circuit breaker contact pair comprises applying a high frequency test voltage across the circuit breaker contact pair, wherein the frequency of the test signal is selected to match the resonant frequency of the circuit breaker contact and that of the filter circuit; and

f. electrically coupling (701) each circuit breaker contact (106) to ground by means of cables in series with inductances.


 
2. A method in accordance with Claim 1 wherein measuring the output voltage across a filter circuit (304) comprises measuring the output voltage across a filter circuit electrically coupled in series with the circuit breaker contact pair.
 
3. A method in accordance with Claim 2 wherein measuring the output voltage across a filter circuit (304) comprises measuring the output voltage across a filter circuit that includes a resistor (306), a capacitor (308), and an inductor (310) electrically coupled in parallel.
 
4. A method in accordance with Claim 2 wherein measuring the output voltage across a filter circuit (304) comprises measuring the output voltage across a filter circuit (304) that is resonant at the test signal frequency.
 
5. A method in accordance with any preceding Claim wherein changing a state of the circuit breaker contact pair comprises changing the state of the circuit breaker contact pair automatically during execution of an automatic test script that include automatic testing procedures.
 
6. A method in accordance with any one of Claims 1 to 5 wherein changing a state of the circuit breaker contact pair comprises changing the state of the circuit breaker contact pair automatically during an automatic test script that include automatic testing procedures executing on a microprocessor.
 
7. A method in accordance with any preceding Claim wherein detecting a step change of the output voltage further comprises:

determining a threshold voltage level for a first contact touch position of the circuit breaker contacts moving from at least one of an open position to a closed position, and a closed position to an open position;

comparing the detected step change of the output voltage to the determined threshold level; and

generating an output signal based on the comparison.


 
8. A method in accordance with any preceding Claim, wherein said high frequency test voltage is a high frequency sine wave test voltage.
 


Ansprüche

1. Verfahren (700) zur Analyse eines Schaltgeräts (100), das mindestens ein Kontaktpaar (106) aufweist, das mindestens einen beweglichen Kontakt (106) umfasst, wobei das Verfahren Folgendes aufweist:

a. Anlegen einer Prüfspannung über ein Leistungsschalter-Kontaktpaar, aufweisend Anlegen der Prüfspannung von einer Leistungsschalter-Prüfvorrichtung (300), die elektrisch über den Leistungsschalter-Kontakt gekuppelt ist;

b. Messen (704) eines Ausgangsspannungssignals, das proportional einer Kapazitanz des Leistungsschalter-Kontaktpaares ist, wobei das Messen der Ausgangsspannung ein Messen der Ausgangsspannung über eine Filterschaltung (304) umfasst;

c. Ändern eines Status (706) des Leistungsschalter-Kontaktpaares von mindestens einer von einer Öffnungsstellung in eine Schließstellung und der Schließstellung in die Öffnungsstellung; und

d. Erkennen (708) einer Schrittänderung bei der Ausgangsspannung (312), die der Statusänderung des Leistungsschalters entspricht, wobei

e. der Schritt des Anlegens einer Spannung über das Leistungsschalter-Kontaktpaar Anlegen einer Hochfrequenz-Prüfspannung über das Leistungsschalter-Kontaktpaar umfasst, wobei die Frequenz des Prüfsignals so gewählt wird, dass sie der Resonanzfrequenz des Leistungsschalterkontakts und der Filterschaltung entspricht; und

f. elektrisches Kuppeln (701) jedes Leistungsschalterkontakts (106) an Masse mithilfe von in Reihe geschalteten Kabeln mit Induktanzen.


 
2. Verfahren nach Anspruch 1, wobei das Messen der Ausgangsspannung über eine Filterschaltung (304) ein Messen der Ausgangsspannung über eine elektrisch in Reihe mit dem Leistungsschalter-Kontaktpaar gekuppelte Filterschaltung umfasst.
 
3. Verfahren nach Anspruch 2, wobei das Messen der Ausgangsspannung über eine Filterschaltung (304) ein Messen der Ausgangsspannung über eine Filterschaltung umfasst, die einen Widerstand (306), einen Kondensator (308) und eine Drossel (310) aufweist, die elektrisch parallelgeschaltet sind.
 
4. Verfahren nach Anspruch 2, wobei das Messen der Ausgangsspannung über eine Filterschaltung (304) ein Messen der Ausgangsspannung über eine Filterschaltung (304) umfasst, die resonant bei der Prüfsignalfrequenz ist.
 
5. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Ändern eines Status des Leistungsschalter-Kontaktpaares ein Ändern des Status des Leistungsschalter-Kontaktpaares automatisch während der Ausführung eines automatischen, automatische Prüfvorgänge umfassenden Prüfskripts aufweist.
 
6. Verfahren nach einem der Ansprüche 1 bis 5, wobei das Ändern eines Status des Leistungsschalter-Kontaktpaares ein Ändern des Status des Leistungsschalter-Kontaktpaares während eines automatischen Prüfskripts auf einem Mikroprozessor aufweist.
 
7. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Erkennen einer Schrittänderung der Ausgangsspannung ferner Folgendes aufweist:

Bestimmen eines Schwellenspannungsniveaus für eine erste Berührungsposition der Leistungsschalterkontakte bei Bewegung von mindestens einer von einer Öffnungsstellung in eine Schließstellung und der Schließstellung in die Öffnungsstellung;

Vergleichen der erkannten Schrittänderung der Ausgangsspannung in das bestimmte Schwellenniveau; und

Erzeugen eines Ausgangssignals auf Basis des Vergleichs.


 
8. Verfahren nach einem der vorhergehenden Ansprüche, wobei die Hochfrequenz-Prüfspannung eine Hochfrequenz-Sinuswellen-Prüfspannung ist.
 


Revendications

1. Procédé (700) pour analyser un disjoncteur (100) qui comprend au moins une paire de contacts (106) qui comprend au moins un contact mobile (106), ledit procédé comprenant :

a. l'application d'une tension de test aux bornes d'une paire de contacts de disjoncteur comprenant l'application de la tension de test à partir d'un dispositif de test de disjoncteurs (300) couplé électriquement aux bornes du contact de disjoncteur ;

b. la mesure (704) d'un signal de tension de sortie qui est proportionnel à une capacité de la paire de contacts de disjoncteur, dans lequel la mesure de la tension de sortie comprend la mesure de la tension de sortie aux bornes d'un circuit de filtrage (304) ;

c. le changement d'état (706) de la paire de contacts de disjoncteur d'au moins un entre un changement d'une position ouverte à une position fermée et un changement de la position fermée à la position ouverte ; et

d. la détection (708) d'une variation brusque de la tension de sortie (312) qui correspond au changement d'état du disjoncteur, dans lequel

e. l'étape d'application d'une tension aux bornes de la paire de contacts de disjoncteur comprend l'application d'une tension de test à haute fréquence aux bornes de la paire de contacts de disjoncteur, dans lequel la fréquence du signal de test est sélectionnée pour correspondre à la fréquence de résonance du contact de disjoncteur et celle du circuit de filtrage ; et

f. le couplage électrique (701) de chaque contact de disjoncteur (106) à la terre au moyen de câbles en série avec des inductances.


 
2. Procédé selon la revendication 1, dans lequel la mesure de la tension de sortie aux bornes d'un circuit de filtrage (304) comprend la mesure de la tension de sortie aux bornes d'un circuit de filtrage couplé électriquement en série avec la paire de contacts de disjoncteur.
 
3. Procédé selon la revendication 2, dans lequel la mesure de la tension de sortie aux bornes d'un circuit de filtrage (304) comprend la mesure de la tension de sortie aux bornes d'un circuit de filtrage qui comprend une résistance (306), un condensateur (308) et une inductance (310) couplés électriquement en parallèle.
 
4. Procédé selon la revendication 2, dans lequel la mesure de la tension de sortie aux bornes d'un circuit de filtrage (304) comprend la mesure de la tension de sortie aux bornes d'un circuit de filtrage (304) qui est résonant à la fréquence de signal de test.
 
5. Procédé selon l'une quelconque des revendications précédentes, dans lequel le changement d'un état de la paire de contacts de disjoncteur comprend le changement de l'état de la paire de contacts de disjoncteur de manière automatique durant une exécution d'un script de test automatique qui comprend des procédures de test automatique.
 
6. Procédé selon l'une quelconque des revendications 1 à 5, dans lequel le changement d'un état de la paire de contacts de disjoncteur comprend le changement de l'état de la paire de contacts de disjoncteur de manière automatique durant un script de test automatique qui comprend des procédures de test automatique, exécuté sur un microprocesseur.
 
7. Procédé selon une quelconque revendication précédente, dans lequel la détection d'une variation brusque de la tension de sortie comprend en outre :

la détermination d'un niveau de tension de seuil pour une première position de toucher de contact des contacts de disjoncteur se déplaçant d'au moins un entre un déplacement d'une position ouverte à une position fermée et un déplacement d'une position fermée à une position ouverte ;

la comparaison de la variation brusque détectée de la tension de sortie au niveau de seuil déterminé ; et

la génération d'un signal de sortie sur la base de la comparaison.


 
8. Procédé selon une quelconque revendication précédente, dans lequel ladite tension de test à haute fréquence est une tension de test sinusoïdale à haute fréquence.
 




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Cited references

REFERENCES CITED IN THE DESCRIPTION



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Patent documents cited in the description