Information
-
Patent Grant
-
6414579
-
Patent Number
6,414,579
-
Date Filed
Monday, December 6, 199925 years ago
-
Date Issued
Tuesday, July 2, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Donovan; Lincoln
- Nguyen; Tuyen T.
Agents
- Thompson; John F.
- Breedlove; Jill M.
-
CPC
-
US Classifications
Field of Search
US
- 336 174
- 336 175
- 336 173
- 336 90
- 336 98
- 336 92
- 335 18
- 361 42
-
International Classifications
-
Abstract
A current transformer for a ground fault circuit breaker used on a circuit having at least one line conductor and a neutral conductor includes a toroidal core having a circular opening defining a center point and a multi-turn winding wound on the core. A first guide member is disposed on one side of the core, and a second guide member is disposed on another side of the core. The first and second guide members each have a hole for receiving the line conductor and a hole for receiving the neutral conductor formed therein. The guide members thus position the conductors with respect to the core. Also included is a method of correcting asymmetries in the current transformer. The method includes measuring the magnitude and orientation of any asymmetries, and then altering the current transformer based on the measured magnitude and orientation of the asymmetries so as to eliminate the asymmetries.
Description
BACKGROUND OF THE INVENTION
This invention relates generally to current transformers and more particularly to current transformers used in ground fault circuit breakers.
Ground fault circuit breakers for alternating current distribution circuits are commonly used to protect people against dangerous shocks due to line-to-ground current flow through someone's body. Ground fault circuit breakers must be able to detect current flow between line conductors and ground at current levels as little as 5 milliamperes, which is much below the overload current levels required to trip conventional circuit breakers. Upon detection of such a ground fault current, the contacts of the circuit breaker are opened to deenergize the circuit.
Current transformers are an integral part of ground fault circuit breakers in that such circuit breakers typically include two of the transformers. A first current transformer, referred to as the ground fault or sense transformer, is used to sense ground fault currents. The sense transformer has as its primary windings the conductors of the distribution circuit being protected, which are encircled by the core, and a multi-turn winding wound on the core. (In the case of a one pole breaker, the line and neutral conductors both go through the sense transformer core, and in the case of a two pole breaker, the two line conductors and the neutral conductor all go through this core. For the sake of example, the following discussion relates to a one pole breaker.) During normal conditions, the current flowing in one direction through the line conductor will return in the opposite direction through the neutral conductor. This produces a net current flow of zero through the transformer, and the multi-turn winding provides no output. However, if a fault (that is, a leakage path) is established between the line conductor and ground, return current will bypass the transformer and flow through the ground back to the grounded side of the source supplying the circuit. Thus, more current will be flowing in one direction through the transformer than in the other, producing a current imbalance. Such a current imbalance produces uncancelled flux in the sense transformer's core, resulting in an output from the multi-turn winding that trips the circuit breaker mechanism.
A second current transformer, referred to as the ground neutral transformer, is commonly used to detect neutral-to-ground faults. A neutral-to-ground fault is an inadvertent short between the neutral conductor and ground that may occur due to a fault such as a wiring error by the electrician installing the circuit breaker. Such a leakage path on the load side of the sense transformer does not in itself produce a shock hazard; however, the occurrence of a grounded neutral at the same time as a ground fault on a line conductor will cause the ground fault circuit breaker to be less sensitive in detecting ground fault currents, thereby creating a hazardous situation. A neutral-to-ground fault reduces the sensitivity of the sense transformer as a ground fault sensing device because such a fault tends to provide a return current path via the neutral conductor for a large portion of the line-to-ground leakage current. To the extent that line-to-ground leakage current returns to the source via the neutral conductor, it escapes detection by the sense transformer. Consequently, the sense transformer may not respond to a hazardous ground fault.
In one known application, the ground neutral transformer comprises a core that encircles the neutral conductor (the ground neutral core can, but need not, encircle the line conductor too) and has a multi-turn winding wound thereon. When a neutral-to-ground fault occurs, an inductively coupled path between the sense transformer and the ground neutral transformer is closed. The resultant coupling produces an output in the ground fault sense transformer that trips the circuit breaker mechanism.
Such circuit breakers provide generally satisfactory operation. However, because of a current transformer's finite permeability, a dipolar asymmetry in the magnetic properties of the transformer's core and/or multi-turn winding will exist if the conductors are not symmetrically located in the opening of the transformer. The sense transformer of a ground fault circuit breaker must be able to detect a current imbalance as little as 5 milliamperes in the presence of hundreds of amperes of current. Thus, even a small dipolar asymmetry can produce an unacceptable error that will degrade the sense transformer's ability to detect ground fault currents.
Conventional current transformers often address this problem with magnetic shielding around the core, but magnetic shielding adds considerable cost to the current transformer. Magnetic shielding also increases the volume of the transformer. This can be a problem in ground fault circuit breakers because it can be difficult to package two transformers, the large #12 or #14 conductors, and a printed circuit board (which contains standard circuit breaker circuitry), into the small allotted volume provided in existing circuit breaker housings. This is particularly the case in residential applications for which compact, half-inch circuit breakers are now available.
It is also known to use high saturation core materials, such as those available under the trademark Permalloy, to minimize the dipolar asymmetry. However, such materials are typically more expensive than other common core materials such as ferrite.
Accordingly, there is a need for a current transformer that provides accurate output without using magnetic shielding or expensive materials.
SUMMARY OF THE INVENTION
The above-mentioned need is met by exemplary embodiments of the present invention which provide a current transformer for a ground fault circuit breaker used on a circuit having one or more line conductors and a neutral conductor. The current transformer includes a toroidal core having a circular opening defining a center point and a multi-turn winding wound on the core. A first guide member is disposed on one side of the core, and a second guide member is disposed on another side of the core. The first and second guide members each have a hole for receiving the line conductor and a hole for receiving the neutral conductor formed therein. The guide members thus position the conductors with respect to the core. In addition, a method of correcting asymmetries in the current transformer is provided. The method includes measuring the magnitude and orientation of any asymmetries, and then altering the current transformer based on the measured magnitude and orientation of the asymmetries so as to eliminate the asymmetries.
The present invention and its advantages over the prior art will become apparent upon reading the following detailed description and the appended claims with reference to the accompanying drawings.
DESCRIPTION OF THE DRAWINGS
The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the concluding part of the specification. The invention, however, may be best understood by reference to the following description taken in conjunction with the accompanying drawing figures in which:
FIG. 1
is a schematic, cross-sectional view of an exemplary embodiment of the current transformer of the present invention.
FIG. 2
is a plan view of a guide disk from the current transformer of FIG.
1
.
FIG. 3
is a schematic representation of a first approach to correcting asymmetries in a transformer.
FIG. 4
is a schematic representation of a second approach to correcting asymmetries in a transformer.
DETAILED DESCRIPTION OF THE INVENTION
Referring to the drawings wherein identical reference numerals denote the same elements throughout the various views,
FIG. 1
schematically shows a current transformer
10
in cross-section. In a preferred embodiment of the present invention, the current transformer
10
is used in a ground fault circuit breaker that is connected in a two-way alternating current circuit line that delivers electrical energy from a power source (not shown) to a load (not shown). The circuit line has a line conductor
12
and a neutral conductor
14
grounded at the power source as is known in the art. While a transformer in a ground fault circuit breaker is being used as an example to facilitate disclosure of the present invention, it should be recognized that the current transformer of the present invention is not limited to use in ground fault circuit breakers and can be used in many transformer applications.
The current transformer
10
includes a toroidal core
16
having a circular opening that defines a center point. The core
16
encircles both the line conductor
12
and the neutral conductor
14
, so that the conductors
12
and
14
function as the single turn winding of the transformer
10
. The core
16
is fabricated using a magnetic material, preferably a relatively inexpensive core material such as iron or ferrite. The transformer
10
also includes a multiturn winding
18
that is uniformly wound on the core
16
. In a ground fault circuit breaker, the multi-turn winding
18
is electrically connected to conventional circuitry, which, in response to a multi-turn winding output, triggers a trip device that opens the breaker contacts, thereby deenergizing the conductors
12
and
14
.
The transformer
10
includes a pair of guide members
20
disposed on opposite sides of the core
16
. Each guide member
20
has a flat disk portion
22
and a cylindrical extension
24
extending perpendicularly from the disk portion
22
. The cylindrical extension
24
is centered with respect to the disk portion
22
and has a radius that is smaller than the radius of the disk portion
22
, but greater than the inside radius of the core
16
with the multi-turn winding
18
. Thus, the cylindrical extension
24
fits snugly within the circular opening of the toroidal core
16
, thereby centering the disk portion
22
with respect to the core
16
. The guide members
20
are made of a non-conducting material such as plastic or fiberglass.
Each guide member
20
has two holes
26
formed therein through which the line and neutral conductors
12
and
14
, respectively, are inserted. As best seen in
FIG. 2
, which shows a single guide member
20
, the holes
26
of each guide member
20
are both located very close to the center of the disk portion
22
and are arranged symmetrically with respect to the center of the disk portion
22
. By virtue of the cylindrical extension
24
centering the disk portion
22
with respect to the core
16
, the holes
26
of each guide member
20
are also located symmetrically with respect to the core
16
. Thus, the guide members
20
assure that the line and neutral conductors
12
and
14
are symmetrically located in the opening of the core
16
, thereby reducing and controlling the dipolar magnetic field from the single turn winding (i.e., the conductors
12
and
14
) of the transformer
10
, and thereby reducing dipolar asymmetry without using magnetic shielding or expensive core materials. By locating the holes
26
of each guide member
20
as close as possible to the center point of the corresponding disk portion
22
, the effect of quadripole and higher moments will be minimized.
The holes
26
are all sized such that the line conductor
12
and the neutral conductor
14
will fit tightly within its corresponding holes
26
. Thus, the guide members
20
will be held in place against the top and bottom of the core
16
by a friction fit between the conductors
12
and
14
and the guide members
20
. Optionally, the guide members
20
could be bonded to the core
16
with a suitable adhesive.
Although exemplary embodiments of the present invention have been described in terms of a one pole circuit breaker having one line conductor and one neutral conductor, and thus two holes
26
in each guide member
20
, the present invention is also applicable to other breakers such as two pole breakers. In this case, each guide conductor would have three holes for the two line conductors and the neutral conductor. The three holes would be arranged symmetrically with respect to the center of the guide member.
Even with the conductors
12
and
14
located symmetrically in the opening of the core
16
, dipolar asymmetries can arise due to asymmetries in the core material and geometry and/or asymmetries in the multi-turn winding
18
. In order to avoid using magnetic shielding, a method of manufacturing the current transformer
10
is provided herein whereby inexpensive materials and manufacturing methods are used to produce a transformer, and then additional steps are taken to correct asymmetries arising in the core
16
and/or the multi-turn winding
18
.
One such approach includes measuring the magnitude and orientation of the asymmetries of the core
16
prior to winding. As shown schematically in
FIG. 3
, the unwound core
16
is excited by a cylindrical excitation conductor
28
located exactly at the core's center of symmetry, and a pick-up coil
30
is placed next to the core
16
, oriented in a direction to pick up only the radial component of the resulting magnetic field. The conductor
28
is connected to an excitation source
32
, and the output of the pick-up coil
30
is monitored. Since the field from the conductor
28
is precisely tangential, there will not be any direct coupling between the conductor
28
and the pick-up coil
30
. Furthermore, if the core
16
is precisely symmetrical, the paramagnetically induced field will also have no radial component. But if the core
16
is not perfectly circularly symmetrical, the induced field will be unbalanced, and a radial component will result. The magnitude of the radial component will be detected by the pick-up coil
30
.
The orientation of this radial component can be determined by rotating the core
16
about its axis of symmetry and noting the sinusoidal variation from the pick-up coil
30
with the angle of rotation. A conventional computer would analyze these variations and calculate the amount and location of core material that needs to be removed or added to eliminate the built-in core asymmetry. If core material is needed to be removed this could be accomplished with a grinder. If core material is needed to be added, this could be accomplished by using a paint applicator to apply a magnetic pigment, such as ferrite or powdered iron, to the appropriate location of the core
16
.
As an alternative to rotating the core
16
to determine the orientation of the induced field, two pick-up coils can be provided at right angles to each other. These coils will pick up the sine and cosine components of the field, and from these, the magnitude and angle of the induced field can be determined.
A second approach includes measuring the magnitude and orientation of the asymmetries of the transformer
10
after the multi-turn winding
18
has been wound on the core
16
. Referring to
FIG. 4
, the core
16
is shown with the multi-turn winding
18
wound thereon and the multi-turn winding leads
34
extending therefrom. A pick-up coil
36
is located in the opening of the core
16
, at the center of symmetry. The multi-turn winding leads
34
are connected to an excitation source
38
so that the multi-turn winding
18
is excited, and the output of the pick-up coil
36
is monitored. The pick-up coil
36
functions as a transformer winding in that if the multi-turn winding
18
is excited and there is zero pick-up in the pick-up coil
36
, then there will also be zero pick-up in the multi-turn winding
18
when the pick-up coil is excited due to the reciprocity of transformers. Since the pick-up coil generates a dipole field, a zero pick-up condition will occur when there is no dipole component to the transformer leakage field. But when there is a non-zero pick-up in the pick-up coil
36
, this is an indication of a dipolar asymmetry in the core
16
and/or multi-turn winding
18
.
The orientation of the induced field can be determined by rotating the core
16
about its axis of symmetry and noting the sinusoidal variation from the pickup coil
36
with the angle of rotation. A conventional computer would analyze these variations and calculate the amount and location of the asymmetry. In this second approach, it would is not practical to make adjustments to the core
16
since it is covered with the multi-turn winding
18
. Thus, corrections to the transformer
10
can be made by spraying magnetically loaded paint on an appropriate location of the wound core, or by adding an arcuate strip of magnetic material adjacent to the outer radius of the wound core. Another technique would be to add an additional winding that has the opposite coupling as the induced field to the core
16
. Typically, such an additional winding will have only a few turns that are generally all wound in a small, selected region.
Again, as an alternative to rotating the core
16
to determine the orientation of the induced field, two pick-up coils can be provided at right angles to each other. These coils will pick up the sine and cosine components of the field, and from these, the magnitude and angle of the induced field can be determined.
An alternative to modifying the properties of the core and/or the winding, which may be sufficient in some applications, is to orient the guide holes with respect to the core such that the dipole field induced by the two wires is orthogonal to the dipole field induced by the asymmetries of the core or winding. Under these conditions, the dipole field induced by the load current and the neutral return current will not induce any pick-up in the multi-turn winding. Although this will work in single pole applications, it does not work in two pole breakers where three conductors pass through the core and the orientation of the dipole cannot be determined.
The foregoing has described a current transformer that minimizes dipolar asymmetries without using magnetic shielding or expensive core materials. While specific embodiments of the present invention have been described, it will be apparent to those skilled in the art that various modifications thereto can be made without departing from the spirit and scope of the invention as defined in the appended claims.
Claims
- 1. A current transformer for use with at least a first conductor and a second conductor, the current transformer comprising:a toroidal core having a circular opening defining a center point; a multi-turn winding wound on said core; a first guide member disposed on one side of said core, said first guide member having a plurality of holes formed therein; and a second guide member disposed on another side of said core, said second guide member having a plurality of holes formed therein wherein said plurality of holes in said first guide member and said plurality of holes in said second guide member are adapted such that said first conductor and said second conductor extend substantially straight between said first guide member and said second guide member.
- 2. The current transformer of claim 1 wherein said holes in said first guide member are arranged symmetrically with respect to said first guide member, and said holes in said second guide member are arranged symmetrically with respect to said second guide member.
- 3. The current transformer of claim 1 wherein said first guide member comprises a first disk portion having a center point and a first cylindrical extension extending perpendicularly from said first disk portion, and said second guide member comprises a second disk portion having a center point and a second cylindrical extension extending perpendicularly from said second disk portion.
- 4. The current transformer of claim 3 wherein said first and second cylindrical extensions fit snugly within said circular opening of said core.
- 5. The current transformer of claim 4 wherein said first cylindrical extension is centered with respect to said first disk portion and said second cylindrical extension is centered with respect to said second disk portion.
- 6. The current transformer of claim 5 wherein said holes in said first guide member are arranged symmetrically with respect to said center point of said first disk portion, and said holes in said second guide member are arranged symmetrically with respect to said center point of said second disk portion.
- 7. The current transformer of claim 6 wherein said holes in said first guide member are located close to said center point of said first disk portion, and said holes in said second guide member are located close to said center point of said second disk portion.
- 8. In a ground fault circuit breaker for use on a circuit having at least one line conductor and a neutral conductor, a current transformer comprising:a toroidal core having a circular opening defining a center point; a multi-turn winding wound on said core; a first guide member disposed on one side of said core, said first guide member having a hole for receiving said at least one line conductor and a hole for receiving said neutral conductor formed therein; and a second guide member disposed on another side of said core, said second guide member having a hole for receiving said at least one line conductor and a hole for receiving said neutral conductor formed therein wherein said at least one line conductor and said neutral conductor extend substantially straight between said first guide member and said second guide member.
- 9. The current transformer of claim 8 wherein said holes in said first guide member are arranged symmetrically with respect to said first guide member, and said holes in said second guide member are arranged symmetrically with respect to said second guide member.
- 10. The current transformer of claim 8 wherein said first guide member comprises a first disk portion having a center point and a first cylindrical extension extending perpendicularly from said first disk portion, and said second guide member comprises a second disk portion having a center point and a second cylindrical extension extending perpendicularly from said second disk portion.
- 11. The current transformer of claim 10 wherein said first and second cylindrical extensions fit snugly within said circular opening of said core.
- 12. The current transformer of claim 11 wherein said first cylindrical extension is centered with respect to said first disk portion and said second cylindrical extension is centered with respect to said second disk portion.
- 13. The current transformer of claim 12 wherein said holes in said first guide member are arranged symmetrically with respect to said center point of said first disk portion, and said holes in said second guide member are arranged symmetrically with respect to said center point of said second disk portion.
- 14. The current transformer of claim 13 wherein said holes in said first guide member are located close to said center point of said first disk portion, and said holes in said second guide member are located close to said center point of said second disk portion.
- 15. The current transformer of claim 8 wherein said holes for receiving said line conductor are sized such that said line conductor will fit tightly therein and said holes for receiving said neutral conductor are sized such that said neutral conductor will fit tightly therein.
- 16. A current transformer for use with at least a first conductor and a second conductor, the current transformer comprising:a toroidal core having a circular opening defining a center point; a multi-turn winding wound on said core; a first guide member disposed on one side of said core, said first guide member having a plurality of holes formed therein; and a second guide member disposed on another side of said core, said second guide member having a plurality of holes formed therein wherein said plurality of holes in said first guide member and said plurality of holes in said second guide member are positioned such that said first conductor and said second conductor extend straight between said first guide member and said second guide member.
- 17. A current transformer for use in ground fault circuit breaker connected to at least one line conductor and a neutral conductor, a current transformer comprising:a toroidal core having a circular opening defining a center point; a multi-turn winding wound on said core; a first guide member disposed on one side of said core, said first guide member having a hole for receiving said at least one line conductor and a hole for receiving said neutral conductor formed therein; and a second guide member disposed on another side of said core, said second guide member having a hole for receiving said at least one line conductor and a hole for receiving said neutral conductor formed therein wherein said at least one line conductor and said neutral conductor extend straight between said first guide member and said second guide member.
US Referenced Citations (7)
Foreign Referenced Citations (1)
Number |
Date |
Country |
0531554 |
Jun 1991 |
EP |