FR2719379A1 - Electrical current sensor for multi-phase electricity meter - Google Patents

Abstract

The sensor includes a generator (8) which generates a voltage signal applied to a module (5) which supplies two identical separated signals. One of the signals is applied to a coder-comparator (3) while the other is applied to the analogue input of a sample generator (7).A converter (2) generates an image voltage which is representative of the current measured (I) which flows through a cable (1). The voltage is applied to the coder-comparator where it is compared with the reference signal. A second module (4) receives the coded output of the coder and sends it to a controller (6) which constitutes the operator interface.

Description

I The present invention relates to a measurement method making it possible to obtain

  isolated samples of a high current

circulating in an electric wire.

  In the field of electronics, it is quite usual to measure a current flowing in a wire. If the intensity of the current to be measured is high (a hundred amps, for example), if this current can be both direct and alternating, if the current sensor must insulate between the wire traversed by said current and the circuit exploiting the output signal of said sensor, if the sensor must be able to recover its initial characteristics after a transient overcurrent several times greater than the maximum current to be measured (30 times, for example), if high precision must be guaranteed for a long time duration (1.5% for 20 years, for example) and if it is absolutely necessary to reach the lowest price for the desired function, then among 15 the multitude of current sensors existing only the current sensors using a magneto- element (Hall effect probe,

  magneto-resistance, thin film, to name only the most commonly used types).

  All current sensors using a magneto-element exploit the magnetic field prevailing in the vicinity of the wire when the latter is

  traversed by the current to be measured, guarantee the insulation between said wire and the output of said sensor, output an analog signal, are robust and inexpensive. They can be classified into two families depending on whether the measurement principle is direct25 or by canceling the magnetic flux.

  A magneto-element current sensor used in direct measurement generally consists of a torus of magnetic material, split, surrounding the wire traversed by the current to be measured and comprising in its slot the magneto-element. The magnetic field prevailing in the vicinity of the wire traversed by the current to be measured induces in the torus a magnetic flux passing through the magneto-element, the latter then delivering a signal dependent on the flux. This element is always followed by an associated electronic circuit, intended to amplify the output signal while correcting certain faults (non-linearities, drifts

etc.).

  A magneto-element current sensor whose operation is based on the cancellation of the magnetic flux differs from a direct measurement model only in that the output of the associated electronic circuit is connected to an additional winding produced on the toroid, says compensation winding. The 5 associated electronic circuit in this case having the function of canceling the signal provided by the magneto-element, therefore the total magnetic flux in the torus, in

  controlling the current flowing in the compensation winding. Any variation in the total magnetic flux, due to the current to be measured, being constantly canceled out by the compensation current, this is then an image of the current10 to be measured.

  With magneto-element current sensors, whatever the measurement principle, direct or compensated, the fact of having even a very short instant a current which cannot be measured (transient overcurrent15 or frequency too high, for example), inevitably changes the remanent magnetic field in the split torus. This modification is then

  interpreted by the magneto-element as being a direct current to be measured. The sensor will then indicate the presence of a direct current which is actually non-existent. This fault is hardly acceptable in the case of the precise measurement20 of direct currents.

  This analysis shows that in the current state of the art there is no economic solution allowing to measure in isolation, with precision, over a long period, a current of high intensity, continuous or alternating and capable of recovering its initial operation after a transient overcurrent several times greater than the maximum current to be

measured (30 times, for example).

  The object of the present invention is to provide a measurement method making it possible to obtain samples of a current of

  high intensity can be both continuous and alternating, ensuring good accuracy over a long period, economical and insensitive to transient overcurrents several times greater than the maximum current to be measured (30 times, for example).

  The measurement method according to the present invention consists in: * generating an alternating voltage in the form of an invariable voltage ramp, returning to its starting point along a path of any shape and of variable duration. * reproduce this voltage at two points distinct from each other, one of these two voltages being completely isolated, the two voltages being strictly identical; * convert the current to be measured into an image voltage representative of said current, * compare this image voltage, possibly amplified, with the above-mentioned isolated voltage ramp, the change in the result of the comparison serving to trigger the generation of a sample; * transmit in isolation to a sample generator the order triggering the generation of a sample; * producing with said sample generator a voltage sample from the ramp of the aforementioned second voltage, this sample being representative of the image voltage at a given time; * obtain a negligible delay or one that varies slowly between the moment when the result of the comparison changes and the moment when the sample is actually generated; * regularly replace after N samples of the image voltage of the current to be measured, representative of the current to be measured, for the duration of a sample, the image voltage of the current to be measured by a voltage-image25 corresponding to a zero current to be measured ("zero" sampling); * provide a means of identifying the sample generated (sample of the image voltage of a current or sample of "zero"); * pseudo-randomly change the time separating two consecutive ramps, therefore the frequency of the alternating voltage generated, in order to allow a fair exploitation of the measurements in the event of undersampling; The measurement method according to the present invention generates samples marred by an error on "zero" due to the different offsets of the circuits and to the aforementioned delay. The comparison being made with an invariable ramp, the delay will therefore produce an additional "zero" offset. The total "zero" offset varying slowly, the measurement method according to the present invention provides means making it possible to correct

  representative samples of the current measured. The correction consisting in subtracting from each representative sample of the current measures a copy of the last 5 sample from the "zero" obtained.

  The accuracy of the samples obtained by the method according to the present invention remains dependent on the means making it possible to convert the current to

  measure in an image voltage of said current. However, the multiple existing means10 carrying out this conversion are perfectly known to those skilled in the art, the latter having only to choose according to the desired performance.

  The method according to the present invention makes it possible to obtain samples of a high intensity current which can be both direct and alternating in isolation. Furthermore, the method according to the present invention is economical, precise even in the long term and insensitive to overcurrents. transients which may be several times greater than the maximum current in front

  be measured, provided that the means ensuring the conversion of the current to be measured into an image voltage of said current allows this.

  Other characteristics and advantages of the measurement method of the present invention will emerge from the description given below making

  reference to the annexed drawing o: * figure I represents a block diagram illustrating the connections

  between the different means necessary to be able to measure according to the measuring method of the present invention.

  Referring to FIG. 1, it can be seen that the measurement method of the present invention allows the user 9 to obtain, in isolation,

  samples of the current I flowing in the wire 1, the insulation being made at the level of the insulation blocks 4 and 5.

  An electrical signal consisting of an invariable voltage ramp, returning to its starting point along a path of any shape and

  variable duration is provided by generator 8.

  This signal is reproduced at two distinct points by the isolation block 5, these two copies being strictly identical to each other, one

  of it being completely isolated and connected to one of the inputs of the encoder comparator 3 while the other copy is connected to the analog input of a sample generator 7.

  The converter 2 supplies an image voltage representative of the current to be measured I flowing in the wire 1, said image voltage being applied to the input of the encoder comparator 3.10 The encoder comparator 3 compares the voltage coming from the converter 2, possibly amplified, with the voltage ramp coming from the isolation block 5. At the very instant when the result of the comparison changes, a signal is transmitted to the isolation block 4. Cyclically after N transmissions of a signal relating to the supplied voltage by converter 2 and for the duration of a single new transmission, the encoder comparator 3 simulates on the input connected to the

  converter 2 the presence of a voltage corresponding to that supplied by converter 2 when the current to be measured is zero.

  The signal transmitted by the encoder comparator 3 to the isolation block 4 is coded in order to allow the identification of the voltage which has just been compared with the ramp (voltage supplied by the converter 2 corresponding to a current to be measured or corresponding voltage to that supplied by the converter 2 when the current to be measured is zero) .25 The function of the isolation block 4 is to transmit the coded signals coming from the encoder comparator 3 in isolation to one of the

controller inputs 6.

  The controller 6 decodes the signals supplied by the encoder comparator 3 through the isolation block 4, controls the sample generator 7 and dialogues with the user 9. As soon as a new coded signal from the comparator arrives encoder 3, controller 6 orders the generator

  of samples 7 to present on its output connected to the user 9 a sample of the voltage ramp present at this time on its analog input.

  At the same time the controller 6 informs the user 9 of the nature and the presence of a new sample at the output of the sample generator 7.

  From this moment on, the controller 6 prohibits the generation of any new sample until the user 9 obtains a signal indicating the end of the processing of the last sample presented. The samples supplied by the sample generator 7 are representative of the voltage having been compared with the ramp by the comparator

encoder 3.

  The delay existing between the moment when the result of the comparison carried out by the encoder comparator 3 changes until the moment when the sample is actually generated distorts the samples obtained. Since the comparison made by the encoder comparator 3 takes place between the voltage to be sampled and a ramp, the aforementioned delay will therefore have the effect of adding a voltage offset to the sample generated. Said delay may vary, said offset

  voltage will therefore be a dynamic voltage offset that can vary in the same ratio as the delay.

  The samples supplied by the sample generator 7 are assigned a voltage offset equal to the sum of the voltage offsets of the various electronic circuits used plus the above-mentioned dynamic voltage offset. The sum of all these voltage offsets is a slowly varying voltage offset. The measurement method according to the present invention makes it possible to correct this slowly varying voltage offset. When the user 9 is informed of the presence of a sample corresponding to the voltage supplied by the converter 2 when the current to be measured is zero, said user 9 must store this sample and subtract it from the following N samples

  (samples representative of the current to be measured). The choice of N depends on the speed at which the total voltage offset varies.

  The samples supplied by the sample generator 7 and thus corrected are representative of the current to be measured I. In the case where the samples representative of the current to be measured I would risk giving rise to undersampling, the user 9 has

  the possibility of pseudorandomly varying the frequency of the signal leaving the generator 8. This allows fair exploitation of the current samples 5 even in the event of undersampling.

  The measurement method according to the present invention makes it possible to economically produce the isolated and precise long-term current sensors necessary for the manufacture of electronic energy meters.

electric polyphases.

Claims (1)

  1) Measuring method making it possible to obtain samples of a high current flowing in an electric wire in isolation, characterized in that it consists in: * generating an alternating voltage having the form of a voltage ramp invariable, returning to its starting point along a route of any shape and variable duration; * reproduce this voltage at two points distinct from each other, one of these two voltages being completely isolated, the two voltages being strictly identical; * convert the current to be measured into an image voltage representative of said current; * compare this image voltage, possibly amplified, with the aforementioned isolated voltage ramp, the change in the result of the comparison serving to trigger the generation of a sample; * transmit in isolation to a sample generator the order triggering the generation of a sample; * producing with said sample generator a voltage sample from the ramp of the aforementioned second voltage, this sample being representative of the image voltage at a given time; * obtain a negligible or slowly varying delay between the time when the result of the comparison changes and the time when the sample is actually generated; 25 * regularly replace after N samples of the voltage-image of the current to be measured, representative of the current to measuring, for the duration of a sample, the image voltage of the current to be measured by an image voltage corresponding to a zero current to be measured (sampling of "zero"); * provide a means of identifying the sample generated (sample of voltage - image of a current or sample of "zero"); * pseudo-randomly changing the time separating two consecutive ramps, therefore the frequency of the alternating voltage generated, in order to allow a fair exploitation of the measurements in the event of undersampling;