Electrical resistors – Resistance value responsive to a condition – Current and/or voltage
Reexamination Certificate
1999-11-19
2001-11-27
Easthom, Karl D. (Department: 2832)
Electrical resistors
Resistance value responsive to a condition
Current and/or voltage
C338S099000, C338S101000, C338S047000
Reexamination Certificate
active
06323751
ABSTRACT:
BACKGROUND OF THE INVENTION
This invention relates to current limiter devices for general circuit protection including electrical distribution and motor control applications. In particular, the invention relates to current limiter devices that are capable of limiting the current in a circuit when a high current event or high current condition occurs.
There are numerous devices that are capable of limiting the current in a circuit when a high current condition occurs. One known limiting device includes a filled polymer material that exhibits what is commonly referred to as a PTCR (positive-temperature coefficient of resistance) or PTC effect. U.S. Pat. No. 5,382,938, U.S. Pat. No. 5,313,184, and European Published Patent Application No. 0,640,995 A1 each describes electrical devices relying on PTC behavior. The unique attribute of the PTCR or PTC effect is that at a certain switch temperature the PTCR material undergoes a transformation from a basically conductive material to a basically resistive material. In some of these prior current limiter devices, the PTCR material (typically polyethylene loaded with carbon black) is placed between pressure contact electrodes.
U.S. Pat. No. 5,614,881, to Duggal et al., issued Mar. 25, 1997, the entire contents of which are herein incorporated by reference, discloses a current limiter device. This current limiter device relies on a composite material and an inhomogeneous distribution of resistance structure.
Current limiter devices are used in many applications to protect sensitive components in an electrical circuit from high fault currents. Applications range from low voltage and low current electrical circuits to high voltage and high current electrical distribution systems. An important requirement for many applications is a fast current limiting response time, alternately known as switching time, to minimize the peak fault current that develops.
In operation, current limiter devices are placed in a circuit to be protected. Under normal circuit conditions, the current limiter device is in a highly conducting state. When a high current condition occurs, the PTCR material heats up through resistive heating until the temperature is above the “switch temperature.” At this point, the PTCR material resistance changes to a high resistance state and the high current condition current is limited. When the high current condition is cleared, the current limiter device cools down over a time period, which may be a long time period, to below the switch temperature and returns to the highly conducting state. In the highly conducting state, the current limiter device is again capable of switching to the high resistance state in response to future high current condition events.
Known current limiter devices comprise electrodes, electrically conductive composite material, a low pyrolysis or vaporization temperature polymeric binder and electrically conducting filler, combined with an inhomogeneous distribution of resistance structure. The switching action of these current limiter devices occurs when joule heating of the electrically conducting filler in the relatively higher resistance part of the composite material causes sufficient heating to cause pyrolysis or vaporization of the binder. During operation of known current limiter devices, at least one of material ablation and arcing occur at localized switching regions in the inhomogeneous distribution of resistance structure. The ablation and arcing can lead to at least one of high mechanical stresses, which are often in the form of moment mechanical stresses, subjected on the conductive composite material. These high mechanical stresses often lead to the mechanical failure of the composite material.
Therefore, electrically conductive composite materials and their configurations for use in current limiter devices should possess desirable and constant consistent, predictable, or reproducible properties. These properties are suitable for high current multiple use current polymer limiting devices that avoid a build up of undesirable high moment mechanical stresses.
SUMMARY OF THE INVENTION
The invention sets forth a current limiter device comprises at least two electrodes; an interlocked-array electrically conductive composite material structure disposed between the electrodes; interfaces disposed between the electrodes; an inhomogeneous distribution of resistance at the interfaces whereby, during a high current event, adiabatic resistive heating at the interfaces causes rapid thermal expansion and vaporization and physical separation at the interfaces; and means for exerting compressive pressure on the electrically conducting composite material structure. The interlocked-array electrically conductive composite material structure comprises an interlocked-array of spaced apart discrete regions comprising at least one insulating flexible material and at least one electrically conductive composite material.
The invention further provides an electrically conducting composite material structure comprising an interlocked-array electrically conductive composite material structure. The interlocked-array electrically conductive composite material structure comprises an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material.
A further aspect of the invention sets forth a method of current limiter device, in which the current limiter device comprises at least two electrodes; an interlocked-array electrically conductive composite material structure disposed between the electrodes; interfaces between the electrodes and interlocked-array electrically conductive composite material structure; an inhomogeneous distribution of resistance at the interfaces whereby, during a high current event, adiabatic resistive heating at the interfaces causes rapid thermal expansion and vaporization and physical separation at the interfaces; and means for exerting compressive pressure on the interlocked-array electrically conductive composite material structure. The interlocked-array electrically conductive composite material structure comprises an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material. The method comprises manufacturing the interlocked-array electrically conductive composite material structure comprising an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material. The manufacturing of the interlocked-array electrically conductive composite material structure comprises providing a relatively inflexible electrically conductive composite material; forming at least one depression in the relatively inflexible electrical conductive composite material; providing an uncured insulating flexible material; depositing the uncured insulating flexible material in the at least one depression in the relatively inflexible electrically conductive composite material; and curing the insulating flexible material to form the an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material. The remainder of the current limiting method comprises providing the at least two electrodes; and providing the an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material between the at least two electrodes and placing the at least two electrodes and an interlocked-array of spaced apart discrete regions of at least one insulating flexible material and at least one composite material under pressure from the exerting means.
These and other advantages and salient features of the invention will become apparent from the following detailed description, which, when taken in conjunction with the annexed drawings, disclose embodiments of the invention.
REFERENCES:
patent: 2870307 (1959-01-01), Milliken et al.
patent: 3226600 (1965-12-01), Zielasek et al.
patent: 3243753 (1966-03-01), Kohler
Duggal Anil Raj
Lee Minyoung
Levinson Lionel Monty
Easthom Karl D.
General Electric Company
Johnson Noreen C.
Vo Toan P.
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