The invention relates to a current transformer comprising at least two partial circuits each comprising a Rogowski type winding, each of the partial circuits being made in the form of an angular portion of a complete circuit surrounding the primary conductor of the transformer over 360°. The winding of each partial circuit is constituted by a go winding and by a return winding which occupy the angular extent of the partial circuit. The complete circuit is equivalent to a Rogowski type secondary circuit of the transformer. A voltage signal measured on this secondary circuit is thus proportional to the derivative of the current conveyed by the primary conductor.
It is recalled that a Rogowski coil, also referred to as a Rogowski torus, is conventionally in the form of a conductor wound on a former of toroidal shape and made of a material that is not ferromagnetic, thereby giving it excellent characteristics of linearity due to its lack of saturation. One of the difficulties in measuring a primary current by means of a secondary circuit or conductor in the form of a Rogowski coil results from temperature variation in the parameters of the coil, which can lead to large measurement errors. Furthermore, if the coil is not accurately axially symmetrical, measurement of the derivative of the primary current depends on the position of the primary conductor passing through the torus, and also on its orientation. It is known that good axial symmetry requires the conductor winding to be made up at least of two windings, i.e. a winding wound on a go path followed by an analogous winding wound on the opposite return path and having turns wound in the same direction on both the go and the return paths in order to cause flux to be additive for the go and return windings. Such a dual go-and-return winding enables the coil to be unaffected by the electromagnetic fields produced by strong currents conveyed by electrical conductors situated outside the torus.
Current transformers are known in the state of the art that use partial circuits comprising Rogowski type windings. Patent document DE 4 424 368 discloses a complete coil of square shape, presenting axial symmetry relative to the primary conductor which passes through its center. That coil is made up of four portions each constituted by a tube covered in a first layer of conductive material, the layer being etched helically to form a track forming a go winding. The conductive material is covered in an insulating layer and a second layer of conductive material which is likewise helically etched to form a return winding. The four go tracks are connected in series with one another by connection elements interconnecting the tubes, and so are the four return tracks. The complete go track is connected in series with the complete return track, and the complete go-and-return coil made in this way is interrupted at a given location on one of the tubes in order to implement two outlet terminations across the terminals of which it is possible to measure the voltage induced in the coil by the primary current.
That principle of building up a complete Rogowski coil from partial coils in the form of angular portions is also applied in the embodiments disclosed in patent application DE 10 161 370 or U.S. 2003 137 388 A1. In particular, an embodiment is described in which the complete coil is made up by associating eight semi-annular circuit portions in series. Each portion is constituted by a printed circuit board (pcb) forming a half-ring, and a stack of four plates is made to form half of the coil which comprises halves of the go-and-return windings. The two stacks in half-rings are separable at two adjacent angular ends in order to facilitate installing the complete coil around the primary conductor of the transformer. The series connection of the go winding with the return winding is located at a first one of said two adjacent angular ends. The two output terminations of the complete coil are situated at the second angular end which is adjacent to the first. There is thus no electrical connection between these two adjacent angular ends, while nevertheless achieving a dual go-and-return winding over 360° so as to enable the complete coil to present a degree of axial symmetry.
It is known that the voltage vs measured by acquiring (and generally also amplifying) the electromotive force (emf) signal vs across the terminals of a Rogowski coil surrounding a primary conductor over 360° depends on the time derivative of the algebraic measurement of the primary current ip in accordance with the following relationship:
in which S(T) designates the sensitivity of the coil to temperature T during measurement, the constant D designating an amplification factor specific to the system for acquiring the emf vs. The signal vs is thus indirectly an image of the primary current. Below, S0 designates the sensitivity of the coil at a given reference temperature T0. In addition, if a Rogowski type coil is wound on a tube in the form of a circular arc, also referred to as a “former”, extending over an angular sector having a certain angle θ, it is possible to define the sensitivity s0of this portion of the winding at the temperature T0 as being equal to S0×θ/360, where θ is expressed in degrees, S0 being the sensitivity of the complete Rogowski coil extrapolated by extending the winding uniformly over 360° around a circular former. For example, if a complete coil is constituted by connecting in series two semi-annular winding portions as shown in patent application DE 10 161 370, it is possible to define the sensitivity s0 of each winding portion as being equal to half the sensitivity S0 of the complete coil.
Nevertheless, it should be observed that with a Rogowski type winding defined over an angular sector of less than 360°, the measurement of current in a primary conductor is influenced by the position of the conductor relative to the winding, and is a fortiori strongly influenced if said angular sector is less than 180°. By way of example, we take a semi-annular winding disposed perpendicularly to a rectilinear primary conductor so that the conductor is at equal distances from both ends of the winding. Any displacement, even if very small, tending to move the winding away from the primary conductor then leads to a significant decrease in the emf measured across the terminals of the winding, assuming that the primary current is uniform over time. The magnetic field generated by the primary current at a given point decreases with increasing distance between said point and the primary conductor. Consequently, the flux induced in the winding decreases due to the above-mentioned displacement, and the measured image of the primary current is thus attenuated.
For these reasons, and in order to be able to obtain a reliable measurement of a current by means of a Rogowski type winding, it is essential firstly for the winding to make a complete turn around the primary conductor so as to be capable of presenting accurate axial symmetry. In order words, looping the secondary circuit of the transformer over 360° is one of the conditions that are necessary in order to be able to make measurements independently of the position of the primary conductor relative to the secondary. That is why the notion of the sensitivity of a Rogowski type winding generally appears in the literature relating to this technical field only for a winding that forms a torus, or for a set of windings connected in series in order to make up a complete turn. In known current transformer devices using windings made up of portions of a complete Rogowski coil, such as the transformer shown in patent application DE 10 161 370, for example, each winding is always connected electrically in series with at least one analogous winding formed by another coil portion so that together these portions make up a complete Rogowski coil surrounding a primary conductor over 360°.
In an embodiment having two semi-annular windings connected in series, the sensitivity of the complete annular winding is practically equal to that of a single winding having the same dimensions. Furthermore, providing the series connection is sufficiently short to disturb the uniformity of the windings in the junction zone between the two windings as little as possible so as to conserve almost perfect axial symmetry, measurement can remain almost independent of the position of the primary conductor. The relative extra cost implied by such an embodiment based on separable windings compared with a conventional winding on a closed support can be justified in particular by the ease with which the complete winding can be installed around the primary conductor. There also exists a particular context in which it can be advantageous to build up a complete Rogowski coil from partial coils, and without necessarily allowing two partial coils to be separated in order to pass the primary conductor into the loop formed by the complete coil.
As is known from patent document EP 0 573 350, it is advantageous to make a Rogowski coil from a pcb that is substantially square and that is provided with a circular cutout for passing the primary conductor. That type of coil presents perfect axial symmetry, and makes it possible to obtain a go winding and a return winding with a large number of turns with flux of the go and the return windings being additive, thereby obtaining very good sensitivity for the coil, together with very good measurement accuracy of the order of 0.1%. Accuracy also remains stable over time since it is practically insensitive specifically to vibration and to temperature variations that might affect the coil. It is possible to take a measurement that is practically independent of temperature by using a resistor in parallel with the output terminals of the coil, and having resistance that is selected as a function of various parameters of the coil, as taught in patent document EP 0 587 491.
Machines for making pcbs enable boards to be produced in a certain range of sizes. At the date on which the present patent application was filed, it would appear that no machine exists that is capable of obtaining pcbs of dimensions greater than 700 millimeters (mm). Even if such machines should be developed in the future, the cost of manufacturing a pcb of large dimensions will, a priori, remain greater than the cost of a plurality of pcbs assembled together to form a pcb of large size. Certain current measurements made using a Rogowski coil, e.g. on gas-insulated metal-clad electrical gear or lines, require the ring that is formed by the tracks and the printed-through holes of the secondary coil of the transformer to have an inside diameter that is at least of the same order as this value of 700 mm. It should be observed for such diameters, it is very advantageous to make coils out of pcbs in order to be able to conserve measurement accuracy in the 0.1% class, since conventional techniques for making a coil by winding a conductor do not enable coils to be produced that reach this accuracy class.
One technical solution for enabling coils of larger size to be made out of pcbs consists in assembling together a plurality of pcbs in a common plane, each pcb having angular coil portions etched thereon. A first method of interconnecting the angular portions of a complete coil consists in connecting them together electrically in series via conductors specially adapted for this purpose, i.e. in connecting the windings together in series in the same go or return direction at each junction between two adjacent plates, on the same principle as for the connections are made between the etched tubes shown in patent document DE 4 424 368. For example, it is possible to assemble together four quarters of a complete annular coil, each quarter being made from a square pcb of side having length equal to at least half the outside diameter of the annular coil. It is thus possible to make up complete coils using pcb technology up to an outside diameter of about 1400 mm, thereby exceeding the greatest dimensions of the metal cladding around which current transformer secondaries are installed with present-day metal-clad electrical gear or lines.
The secondary circuit of the current transformer implemented by the complete annular coil can thus be installed at atmospheric pressure, e.g. around a double metal shell providing a leaktight connection between two metal cases filled with insulating gas under pressure and having the primary conductor of the transformer passing therethrough. By way of example, the primary conductor is constituted by the conductor of a single-phase metal-clad line. The two shells are connected together by means of a gasket providing sealing relative to the insulating gas, the gasket being made of a material that provides electrical insulation. This enables the return current flowing in the metal cases to pass outside the annular coil, and thus ensures that current measurement is not influenced by the return current.
Nevertheless, the technique consisting in electrically connecting the angular portions of a complete coil together in series can present certain drawbacks, both for a coil in the form of a conventional toroidal winding and for an annular coil made using printed circuit technology. Firstly, a connection via a conductive bridge interconnecting two adjacent portions of the complete coil disturbs the uniformity of the distribution of turns in the junction zone between the windings, to some extent. This can be seen in particular, for example, in
The difficulties in obtaining an electrical junction between two adjacent pcb quarters that is mechanically reliable and that disturbs measurement as little as possible can nevertheless be overcome, in particular when using the technique of a conductive bridge that is flexible. It is thus possible to obtain a complete annular Rogowski coil of large size made up of pcb quarters, and that is electrically equivalent to a coil of the same size and made using a single pcb as taught in patent document EP 0 573 350, naturally assuming that a machine were available enabling a pcb of such size to be made. The two electrical terminations of the complete Rogowski coil are preferably situated at one end of a quarter of the coil beside the junction with the adjacent quarter, said junction then being the only junction which is not crossed by a conductive bridge.
When considering the above technique using Rogowski coil quarters, in particular for pcb technology embodiments as taught by patent document EP 0 573 350, account needs to be taken of the fact that the ring formed by the complete coil of the current transformer may have a diameter that is typically greater than 700 mm in applications to current transformers for gas-insulated metal-clad electrical gear. The total number of turns (each formed by two opposite track segments and by two plated-through holes in a pcb) can then be very large for the complete Rogowski coil. At this stage, it should be recalled that the total sensitivity S0 of a Rogowski coil of large diameter differs little from that of a coil of smaller diameter but having the same density of turns. The increase in sensitivity due to the greater number of turns is counterbalanced by the smaller magnitude of the magnetic field due to the coil being further away from the primary conductor whose current is to be measured.
Thus, even for a coil of large diameter, the parasitic surge voltage signals that might interfere with the emf signal induced in the coil are of relatively large amplitude because the total sensitivity S0 is practically independent of the diameter of the coil. The interfering signals are caused by high frequency currents in the line whose primary current ip is being measured by the transformer. Because the emf signal is proportional to the derivative of the primary current ip, any disturbances at high frequency that affect the primary current will inevitably lead to voltage surges at the terminals of the secondary winding of the transformer. The interfering voltage surge signals must then be processed by an acquisition and processor unit suitable for producing a corrected signal vs (which signal is usually amplified) that is an image of the corrected primary current signal from which the high frequency current disturbances have been filtered.
Because of their relatively large amplitudes, interfering voltage surge signals can be difficult to process when correcting the measured signal, which then leads to measurement of smaller accuracy. Even when high-performance signal correction processing is applied to the emf signal across the terminals of the Rogowski coil in order to obtain very high measurement accuracy, that generally involves cost that is increased compared with obtaining accurately of the same order in a situation where the voltage surge interference signals are of smaller amplitude.
The main object of the invention is to provide a current transformer whose secondary circuit comprises a complete Rogowski coil of large diameter made up from a plurality of angular coil portions that are mechanically assembled together with very good uniformity in terms of axial symmetry for the complete coil, while also having a configuration for the transformer secondary circuit that serves to limit the amplitudes of the interfering voltage surge signals to be processed. A more particular object of the invention is to provide pcb technology embodiments of complete Rogowski coils of large diameter while omitting any conductive bridge between the coils of adjacent partial pcbs making up the complete coil, which embodiments should enable accuracy to be achieved at least of class 0.1% with excellent temperature stability.
To this end, the invention provides a current transformer comprising at least two partial circuits each comprising a Rogowski type winding, each of said partial circuits being made in the form of an angular portion of a complete circuit which surrounds at least one primary conductor of the transformer over 360°, said complete circuit having the function of a Rogowski type secondary circuit for the transformer, the winding of each partial circuit being constituted by a go winding together with a return winding extending over the angular extent of the partial circuit, characterized in that for each partial circuit, said go and return windings are electrically connected in series, both having turns wound in the same direction so as to form a single winding presenting a pair of adjacent electrical terminations, the pairs of electrical terminations of said windings being connected to an acquisition system designed to produce a complete signal which is an image of the primary current of the transformer.
The complete circuit constituted by associating a number N of partial circuits thus presents the same number N of pairs of electrical terminations. As explained below, the emf signals vs(n) measured across the terminals of each partial circuit are transmitted to a summing acquisition system (generally including amplification) designed to recreate a complete signal vs which, at a given reference temperature T0, satisfies the following relationship:
where K designates the overall amplification factor of the summing acquisition system, and S0 designates the sensitivity of the equivalent complete circuit. It is explained below how the resistances of the resistors that define the overall amplification factor can be parameterized so that the factor is insensitive to variations in temperature. It should be observed that S0 is equal to the sensitivity of a complete coil as would be constituted by connecting the windings of the partial circuits in series in order to obtain a configuration equivalent to that described in patent EP 0 573 350, in which configuration the complete coil presents only two electrical terminations for acquiring the emf signal constituting an image of the primary current.
In a current transformer of the invention, and when all of the partial circuits are identical, the sensitivity S0 of the complete equivalent circuit is equal to the sensitivity s0 of a partial circuit multiplied by the number N of partial circuits. Above equation (2) can then be written:
and it is therefore possible to determine the primary current of the transformer by integrating over time the complete signal vs as measured on the Rogowski type secondary circuit.
Preferably, the pair of electrical terminations of a partial circuit is placed at one of the two angular ends of the partial circuit, the go and return windings each traveling over the angular extent of the partial circuit and being electrically connected together in series at the other angular end. This disposition of the terminals at one angular end of a partial circuit makes it possible in particular for the terminals of two adjacent partial circuits to be placed side by side so as to use two relatively short shielded cables of the same length for connecting both circuits to a signal acquisition system. It has been found that it is important for the cables to be both relatively short and of the same length in order to minimize the interfering signals that might be generated in the cabling by the strong electromagnetic field due to the current being conveyed in primary conductors adjacent to the current transformer, and keep them down to levels that do not prevent accuracy being in the 0.1% class.
In a preferred embodiment of a current transformer of the invention, each partial circuit is embodied by a plane or curved pcb having a series of metal tracks on each of its two faces, the tracks in one series being electrically connected to those of the other series via plated-through holes passing through the pcb in order to form the winding of the partial circuit.
In another advantageous embodiment of the current transformer of the invention, one of the two terminations of the winding of each partial circuit is electrically connected to a common reference potential, while the other termination is electrically connected to an input of an acquisition system which provides an amplification function including at least one operational amplifier with a feedback loop. Advantageously, each input of the acquisition system is connected to an operational amplifier input via a resistor of resistance selected so that the voltage signal measured at the output from the acquisition system is independent of variations in the temperature of the secondary circuit of the transformer.
The invention, its characteristics, and its advantages are described in greater detail below with reference to the following figures.
a is a diagram showing a first angular end of the partial circuit of
b is a diagram showing a second angular end of the partial circuit of
a is a diagram of the partial circuit forming one of the quarters making up the complete circuit of
b is a diagram showing one face of one angular end of the partial circuit, of
c is a diagram showing the other face of the angular end of the partial circuit shown in
a is a diagrammatic plan view of the partial circuit shown in
a is a diagram of the two faces of a partial circuit forming one of the quarters constituting the complete circuit of
In
A partial circuit CBn is thus formed in the present case by a quarter of an annular secondary circuit as described in patent EP 0 573 350. Nevertheless, it is not electrically identical to a quarter as would be obtained merely by cutting up a printed circuit constituting a Rogowski coil in the above-specified state of the art. As can be seen in
As can be seen in
In order to simplify the diagrams of
Four identical partial circuits CB1 to CB4 are thus assembled on the annular frame 15, the complete circuit being held on the frame, e.g. by means of circular holes formed through radial projections from the outside edges of the printed circuits. These holes must then be provided so as to pass corresponding cylindrical studs with little clearance, which studs are fixed on the frame, with it being possible for two cylindrical studs to suffice for mounting one partial circuit on the frame. In this embodiment of a complete ring circuit made up of identical partial circuits, two adjacent partial circuits, when seen from the same side of the ring, have alternating A faces and B faces so that their respective two pairs of terminals are disposed side by side. The advantage of this disposition is explained below with reference to the embodiment shown in
The partial circuit CB1 of the complete circuit CB shown in
In
a is a diagrammatic plan view of this partial circuit seen looking along direction Y represented by a dashed-line arrow. In known manner, the two series 41 and 42 respectively of tracks etched on the two faces of the plate 4 are interconnected by plated-through holes passing through the thickness of the pcb. The same applies for the two series 51 and 52 respectively of tracks etched on the two faces of the plate 3. The thickness of the insulating layer 5 is preferably smaller than the thickness of either pcb 3 or 4.
The electrical circuit diagram of a current transformer of the invention is shown in
For example, the terminal T11 of the partial circuit CB1 connected to earth at ground potential, and the other terminal T12 is connected to a resistor R1 at the input of the acquisition system 7. As shown diagrammatically in the figure, the winding of each partial circuit CBn must have its turns wound in the same direction on both the go and the return paths respectively in order to have additive flux between the go and return windings Cn0 and Cn1. For example, it can be seen that on going from the terminal T11 to the terminal T12, the go winding C10 and the return winding C11 have their turns wound in the same direction, which is counterclockwise.
Advantageously, the two terminals T1n and T2n of a partial circuit are connected respectively to ground and to one of the inputs E1 to E4 of the acquisition system 7 in a manner that alternates relative to the two terminals T1n+1 and T2n+1 of an adjacent partial circuit. In this way, the output voltage signals vs(1) to vs(4) of the partial circuits are summed in phase by the acquisition system. It is important to avoid these signals being summed in phase opposition, since the voltage signal vs measured at the output terminal 11 of the acquisition system would then be substantially zero. Because the partial circuits are assembled together as shown in
The principle of summing and amplifying as shown by the circuit of
As shown below, the signal vs as measured at the output from the acquisition system 7 is independent of temperature variations providing the resistance of each input resistor R1 of the acquisition system 7 satisfies relationship (9) below.
It is shown above that the sensitivity s of a partial circuit is defined such that the emf signal vs measured across the terminals of a partial circuit satisfies the relationship:
Furthermore, the internal resistance r of the winding of a partial circuit varies linearly with the temperature T of the partial circuit in application of the following relationship which is well known in itself:
r=r0(1+β.δT) (5)
where δT=T−T0, where β is the temperature coefficient for the resistivity of the material constituting the winding, and where T0 is the reference temperature. For example, if the material is copper, then β is about 3900 parts per million per degree Celsius (ppm/° C.).
Similarly, the sensitivity s of a partial circuit varies linearly with the temperature T of the substrate since an expansion of the substrate increases the section of the turns of the partial circuit, with said section being proportional to the thickness of the substrate. This relationship is written as follows:
s=s0(1+αz.δT) (6)
where αz is the coefficient of linear expansion of the substrate in the direction perpendicular to the surface of the substrate. In the embodiment shown in
The current at the inverting input 9 of the operational amplifier 8 is zero assuming that the amplifier is ideal, so Kirchoff's law leads to the following relationship:
where N is the number of partial circuits. Given relationship (4), the following is obtained:
Since the N partial circuits are assumed to be identical and at the same temperature T, it can be assumed that the windings all have the same internal resistance r and the same sensitivity s which satisfy relationships (5) and (6) respectively at said temperature T. Relationship (7) thus becomes:
or indeed:
It can be seen that if the value R1 is selected so as to satisfy the relationship:
then relationship (8) can be written:
Thus, with reference to relationship (2), the overall amplification factor K of the summing acquisition system 7 satisfies the relationship:
or indeed, replacing R1 as a function of relationship (9):
In absolute terms, the resistances R1 and R2 are not completely stable with variations in temperature. But in practice, firstly the temperature coefficient of each resistance can be selected to very small (e.g. less than 5 ppm/° C. for a resistance made of NiCr), and secondly the tiny variations in the respective resistances R1 and R2 as a function of temperature take place together and in the same direction, such that the ratio
can be considered as being completely stable with temperature. The factor K, and thus the measured signal vs is thus independent of variations in temperature. The signal vs is thus a very accurate image of the current ip carried by the primary conductor 10.
The summing acquisition system 7′ comprises two stages of amplification. A first amplification stage in this case comprises two operational amplifiers 8 each handling half of the emf signals vs(n) of the partial circuits. The first amplification stage is thus constituted by two identical amplifying subassemblies 71 and 72 each analogous to the circuit of the acquisition system 7 shown in
The main advantage of this acquisition system 7′ is associated with the disposition of the terminals of the partial circuits of the current transformer. Whatever the number p of complete circuits, two diametrically-opposite groups of terminals are obtained. For example, the terminals of the partial circuits CB1, CB2, CB5, and CB6 are close to one another and form the first group, while the terminals of the remaining partial circuits form the diametrically-opposite, second group. Each group of terminals is electrically connected to an amplifying subassembly 71 or 72, and the length of the same-length cables making up the cabling can be particularly short if each subassembly 71 or 72 is disposed beside its own group of terminals. Effective shielding of each cable and also of each amplifying subassembly allocated to a group of terminals can thus be achieved without major difficulty, so that the two groups of signals vs(n) respectively at the inputs E1 to E4 and E5 to E8 of the acquisition system 7′ are not disturbed by the electromagnetic fields due to currents flowing in primary conductors adjacent to the current transformer.
The signals v71 and v72 produced by the first amplification stage satisfy the following relationships:
The complete signal vs satisfies the following relationship:
Given that the sensitivity S of a complete circuit and the internal resistance r of a partial circuit satisfy the following relationships respectively:
−S=S0(1+αz.δT) and r=r0(1+β.δT)
it is again possible to select R1 so as to satisfy relationship (9), so that the output voltage vs from the acquisition system 7′ is independent of the temperature T of the complete circuits.
Relationship (14) then becomes:
The resistances R3 and R4 can be selected to be identical so that the second amplification stage merely sums the output voltages from the first two stages 71 and 72. The above relationship is then written as follows:
Comparing relationships (10) and (15) shows clearly that the sensitivity equivalent to two identical complete circuits connected in parallel is equal to twice the sensitivity S0 of one complete circuit. In addition, the advantage of having a plurality of complete circuits disposed mutually in parallel is also to enable an increase in the signal-to-noise ratio for the output signal vs of the acquisition system. The signal-to-noise ratio for a number p of identical complete circuits is √{square root over (p)} times greater than the signal-to-noise ratio for a single complete circuit.
It is not essential to use operational amplifiers for a signal acquisition system provided by the secondary circuit of a current transformer of the invention. The sensitivity of each partial circuit of the secondary circuit may be sufficient to obtain a voltage signal vs(n) that is satisfactory across the terminals of a resistance R1 satisfying relationship (9) and interconnecting two adjacent electrical terminations T1n and T2n of the partial circuit. The N signals vs(n) can then be acquired separately, and each can be conveyed to a summing system (with or without amplification) in order to recreate the secondary signal of the complete circuit formed by the N partial circuits. For example, each voltage signal vs(n) across the terminals of a resistance R1 may be acquired by an analog-to-digital converter, with the digital signal then being conveyed optically to a summing system that can be situated remotely from the secondary circuit.
It is also possible to omit the operational amplifier 8′ in the second amplifying/summing stage of the acquisition system 7′ shown in
A current transformer of the invention can thus be used for detecting any residual current.
Number | Date | Country | Kind |
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04 50897 | May 2004 | FR | national |
Number | Name | Date | Kind |
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5414400 | Gris et al. | May 1995 | A |
20030137388 | Meier et al. | Jul 2003 | A1 |
Number | Date | Country |
---|---|---|
44 24 368 | Jul 1995 | DE |
44 24 368 | Jul 1995 | DE |
101 61 370 | Aug 2002 | DE |
0 573 350 | Jun 1993 | EP |
0 573 350 | Dec 1993 | EP |
0 587 491 | Mar 1994 | EP |
0 587 491 | Mar 1994 | EP |
2000065866 | Aug 1998 | JP |
2000-147023 | May 2000 | JP |
Number | Date | Country | |
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20050248430 A1 | Nov 2005 | US |