The present invention is in the field of electrical switches, and more particularly, contactors for high-power direct current (DC) circuits.
In certain circumstances there is a need to interrupt current in a DC circuit while the circuit is carrying a high current (e.g. 50 to 200 amps). These circumstances may arise, for example, when an electrical load on the circuit becomes excessive or when a short-circuit fault develops. In order to accommodate such eventualities, high-current DC circuits may incorporate heavy-duty contactors.
Rapid interruption of current may produce an induced surge of energy. This energy may produce arcing in a contactor. Some heavy-duty contactors may be constructed so that this arcing may be tolerated. Other prior-art contactors may be constructed so that such arcing is reduced.
In some prior-art contactors, a gas-tight or liquid-tight enclosure may be provided for the contactor or its contact elements. A gas or liquid may surround the contact elements and prevent oxidation of the elements when arcing occurs. In other prior-art contactors, selected arc-tolerant metallic alloys may be used for contact elements.
Some prior-art contactors may be provided with an electrical shunt that may by-pass an energy surge around the contact elements. Such a shunt may comprise a high-power field-effect transistor (FET) or similar device. The FET must be able to tolerate a high-current surge without damage. For example, a shunt or by-pass rated at about 1500 amps may be needed for a contactor rated at 150 amps that may be required to open with a “short circuit” condition.
Prior-art high-power contactors with protected contact elements or with by-pass shunts are expensive, heavy and complex. These characteristics of prior-art contactors are of particular concern to aircraft designers. Aircraft designs are evolving in a direction that is often referred to as “more electric architecture” (MEA) design. In new MEA designs various operational functions which were formerly performed with hydraulic and pneumatic systems are now performed electrically. These electrical operations are often performed with high amperage DC motors and controls. In this context, MEA designs may incorporate an increasing number of contactors which may interrupt high-amperage DC. MEA designs could be improved if high-power contactors could be made lighter, less expensive and more reliable than prior-art contactors.
As can be seen, there is a need to provide improved contactors which are capable of interrupting high amperage DC. Additionally, there is a need to provide such contactor with low weight so that they may be effectively employed in aircraft.
In one aspect of the present invention, an apparatus for interrupting current in a circuit comprises contacts through which the current passes. The contacts move away from one another during current interruption. A shunt is provided to by-pass surge power around the contacts when current is interrupted. The shunt is operative during a portion of time period that the contacts move and the shunt is inoperative during a portion of said time period.
In another aspect of the present invention, an electrical power circuit comprises a contactor with movable contacts, an electrical shunt to by-pass current around the contacts, and a pulse control unit to periodically operate the shunt during movement of the contacts.
In still another aspect of the present invention, a method for interrupting current in a circuit under load conditions comprises the steps of moving conducting contacts away from one another for a predetermined time period, detecting electrical power at the contacts during the step of moving the contacts, determining if the detected power is sufficient to initiate arcing at the contacts, operating an electrical shunt around the contacts for a portion of the predetermined time period if the detected power is sufficient for arcing initiation, and disabling the electrical shunt for a portion of the time period.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following drawings, description and claims.
The following detailed description is of the best currently contemplated modes of carrying out the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention, since the scope of the invention is best defined by the appended claims.
Broadly, the present invention may be useful for interrupting high-amperage current in a circuit. More particularly, the present invention may provide light-weight shunted contactors to perform such interruption. The present invention may be particularly useful in vehicles such as aircraft.
In contrast to prior-art contactors, among other things, the present invention may provide a pulse-rated shunt for a contactor. The present invention, instead of employing a prior-art steady-state rated shunt for a contactor, may, utilize a lower-rated shunt. The lower-rated shunts may be operated in a series of conducting pulses to reduce or preclude arcing in a contactor. By avoiding continuous conduction of current through the shunt, a smaller, lower-rated shunt (e.g. an FET) may be used to protect a contactor from arcing damage.
Referring now to
It may be seen that as spacing between the contacts 10 and 12 increases, a combination of Vs and Is must become larger in order for an arc to initiate. Graph lines 102, 104, 106 and 108 may illustrate this concept. Graph line 102 represents a surge-power limit curve for contact spacing of 1.0 mm. Graph lines 104, 106 and 108 may represent surge-power limit curves for contact spacings of 1.5 mm, 1.8 mm and 3.0 mm respectively.
Referring now to
A sloped line 306 may represent a compilation of the surge-power curves of
Referring now to
In
If shunting were not to occur at or before time T1, surge power at the contacts 10 and 12 could continue to increase in accordance with the graph line 308. In such a case, arcing could initiate and continue until surge power is dissipated, i.e., until a time T2 on the graph 300.
If shunting occurs at or before time T1, overall surge power may continue to increase as a function of time but there may be a reduced amount of the surge power at the contacts 10 and 12. The graph line 310 may represent a portion of the surge power at the contacts 10 and 12, i.e., a “contact portion”. A graph line 312 may represent a “shunt portion” of surge power as a function of time.
The shunt portion line 312 may have a pulsed configuration. This configuration may be associated with a novel operation of the shunt switch 24 in accordance with the invention. The switch 24 may be closed at or before the time T1. At that time the surge power may pass through the switch 24. At a later time, T12, the switch 24 may open and surge power may once again be applied to the contacts 10 and 12. An exemplary time period between T1 and T12 may be about 5 to 10 microseconds (μsec). The contact portion of surge power at time T12 may be greater than the contact portion at time T1, but the contacts 10 and 12 may be further apart at the later time T12. If the contact portion of surge power remains below the surge power boundary (line 306) after time T12, then arcing may not initiate.
Surge power may continue rising after time T12. If such rising were left to proceed, the contact portion of surge power may exceed the surge power boundary 306 at a later time T16. But, at or before the time T16 (e.g., at a time T14), the switch 24 may again close. Surge power may once again by-pass the contacts 10 and 12. Consequently the surge power boundary 106 may not be crossed by the contact portion of surge power and arcing may not initiate.
A similar sequence of events may occur at a time T18 when the switch 24 may again open. At the time T18, contact surge power may begin to rise at a rate that may result in the contact portion of surge power crossing the surge power boundary at a later time T22. Such a crossing may be precluded if the switch 24 were to close at or before the time T22 (e.g., at a time T20).
The time period between T1 and T12 may be considered a pulse period 314 for the switch 24. Similarly a time period between T14 and T16 may be considered a pulse period 314 for the switch 24. A series of similar pulse periods 314 may develop during a surge period 316, i.e., a period of time between T0 and T2 required for dissipation of the surge power. For purposes of simplicity, only a few of the switch pulse periods 314 are shown symbolically in
In a pulsed mode of operation, the switch 24 may conduct current during a fractional part of the surge period 316. Pulsed operation of the switch 24 may allow for use of a solid-state switch (e.g. a FET) with a lower current rating lower than a FET that may be required to continuously conduct current throughout the surge period 316. For example, in the prior-art, a FET with a nominal rating of 1500 amps may be required to continuously shunt all of the surge power for an exemplary 150 amp circuit. But, in the case of the present invention, an exemplary FET may be used with a “pulse-rating” of 1500 amps. Pulse rating for an FET may be about 2.5 times as great as its nominal rating. Thus, a FET with a nominal rating of 600 amps (1500 amps/2.5) may be used to provide arc suppression for a contactor in the exemplary 150 amp circuit. In other words, the switch 24 of the present invention may have a nominal rating that is at least 50% lower than a nominal rating of a prior-art shunt switch.
An FET with a nominal rating of 600 amps may be smaller, lighter and less expensive than a FET with a nominal rating of 1500 amps. It may be seen therefore that when contactors are constructed and operated in accordance with the present invention, the contactors may be smaller, lighter and less costly than their prior-art counterparts.
Referring now to
The V1 and V2 signals may be provided to the pulse control unit 400 through a conventional signal conditioning and protection block 404. The pulse control unit 400 may comprise an analog to digital (A/D) converter 406, a multiplier 407 and an arcing-condition determination block 408. The block 408 may analyze a digital representation of the V1 and V2 signals against a clock signal (not shown) to determine if their combined power may initiate arcing between the contacts 10 and 12. The block 408 may perform its analysis repetitively at an exemplary sampling rate of about 0.1 μsec. In the event that arcing potential is determined by the block 408, a driver 410 may be activated to close the solid-state switch 24. This may shunt surge power through the switch 24. If current through the switch 24 increases beyond a predetermined level, an over-current block 412 may produce a signal 412-1 to an OR gate 414. An over-on-time block 416 may determine a length of time that the switch 24 is closed or “on”. This on-time may be compared against a predetermined time (e.g., a switch pulse period of 5 to 10 μsec.). An over-on-time signal 416-1 may be provided to the OR gate 414 after the predetermined amount of on-time for the switch 24. If either of the signals 412-1 or 416-1 are received by the OR gate 414, a switch-opening signal 414-1 may be provided to the driver 410 and the switch 24 may be directed to open. A shunt of current of a desired magnitude and time duration may thus be produced based on the predetermined level of current that may be established in the block 412 and the predetermined time that may be established in the block 416.
Effectiveness of the present invention may be dependent on a proper selection of shunt pulse time. In an exemplary case of a surge period of about 1 msec. it has been found that a shunt pulse period of about 5 μsec may be effective in reducing or even eliminating arcing. One of the contactors 14 may experience some brief arcing (less than 5 μsec in duration) or none at all when the shunt 18 is operated with 5 μsec pulses.
However, it has also been found that a shunt pulse period of about 1 μsec may not effective in reducing or precluding arcing. When, in the same exemplary case, the shunt 18 is operated with pulses of about 1 μsec, an arc may initiate and may continue for about 900 μsec. Thus there appears to be a lower limit for effective shunt pulse time and that lower limit is about 1 μsec.
There may also be an upper limit for effective shunt pulse time in the context of the present invention. The present invention allows for shunting with a solid-state switch employed at its pulse rating. As described in an earlier example, a switch with a pulse rating of 1500 may be much smaller and lighter than a switch with a continuous conduction rating of 1500 amps. In order to safely use the smaller and lighter switch, it must be allowed to conduct for only brief periods, i.e., pulses. If the pulses are too long or are too closely spaced in time, the smaller and lighter switch may no longer perform safely. It has been found that a cumulative elapsed time of all shunt pulses in a single current interruption should not exceed 50% of the surge period. Furthermore, it has been found that no single one of the shunt pulses should exceed 20% of the surge period. In the exemplary case under consideration these principles suggest that a shunt pulse should not exceed 20 μsec.
In one embodiment of the present invention, a method may be provided for interrupting current in a circuit under load conditions. Such a method 500 may be illustrated in flow-chart format in
In a step 502, voltage may be continuously detected at current-interruption contacts (e.g., the voltage V1 may be detected at the contact 10 of the contactor 14). In a step 504, a voltage signal may be produced which is indicative of current at the contacts (e.g., a voltage drop V2 across a resistor may be indicative of current in the conductor 18 as well as current at the contact 12 of the contactor 14).
In step 506 the voltages of steps 502 and 504 may be periodically sampled (e.g., by the arcing-condition determination block 408). In a step 508 a combination of the voltages of steps 502 and 504 may be analyzed to determine if sufficient power is present at the contacts to initiate arcing (e.g. the block 408 may perform an analysis of V1 and V2 and make a time-related comparison to determine if surge power is high enough to initiate arcing). In the event that arcing potential is determined to exist, a step 510 may be initiated in which shunting of current around the contacts may be performed for a predetermined time (e.g., the solid-state switch 24 may be closed responsively to a signal 414-1 from the driver 414). In a step 512, the shunt may be opened (e.g., the switch 24 may open in response to signal 414-1 from the driver 414, which may act responsively to signals 412-1 or 416-1).
After step 512 may be completed, the step 508 may be re-initiated to determine in arcing potential may exist. If arcing potential is determined to exist, step 510 and 512 may be re-initiated. When and if performance of step 508 may determine that arcing potential does not exist, step 510 may not be initiated.
It should be understood, of course, that the foregoing relates to exemplary embodiments of the invention and that modifications may be made without departing from the spirit and scope of the invention as set forth in the following claims.
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Number | Date | Country | |
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