FR2611051A1 - Device for measuring the intensity of an alternating electric current using a Hall probe - Google Patents

Abstract

The invention relates to a device for measuring the intensity of an alternating electric current using a Hall probe. The subject of the invention is a device for measuring the intensity of an alternating electric current, characterised in that it comprises a Hall probe 1, consisting of two electric dipoles, of which one 2 is connected to a so-called control circuit comprising a direct current source 4, and an electric resistor 6, 7, preferably a variable resistor, and the other 3 can deliver to its terminals 9, 10 a signal in the form of a voltage U, the said probe 1 being interposed in a magnetic field H generated by the current whose intensity is to be measured. Application to the measurement of intensity of industrial and domestic alternating electric currents.

Description

DEVICE FOR MEASURING THE INTENSITY OF AN ELECTRIC CURRENT
ALTERNATIVE USING A HALL PROBE
The present invention relates to a device for measuring the intensity of an alternating electric current, industrial or domestic, using a HALL effect probe.

 For measuring the intensities of industrial or domestic alternating electric currents, toroidal coils are generally used, which have two major drawbacks.

 Economically they are of high overall cost and, above all, technically, they are the seat of induced voltages often disturbed by parasitic voltages, of various frequencies, making the processing of useful signals difficult. Thus in very disturbed environments it is almost impossible to differentiate a true signal at 50 Hz from parasitic snoring at the same frequency.

 The object of the invention is to overcome these drawbacks by proposing a new device using HALL effect probes in a new way.

 To this end, the subject of the invention is a device for measuring the intensity of an alternating electric current, characterized in that it comprises a HALL effect probe made up of two electric dipoles, one of which is connected to a said control circuit comprising a direct current source and an electrical resistance which is preferably adjustable and the other of which is capable of delivering at its terminals a signal in the form of a voltage U, said probe being interposed in a magnetic field (H) generated by the current whose intensity is to be measured.

 According to another characteristic relating to the mounting of said device, said probe is interposed between two pieces of non-permanent magnetic material arranged in opposition on either side of the probe, one of the pieces being mounted adjustable in distance from the probe, so as to modify the air gap, the two parts being connected by parts made of non-permanent magnetic material so as to together form a magnetic loop surrounding the conductor in which the current flows, the intensity of which is to be measured.

 Such a device makes it possible to deliver a voltage U across the terminals of said second dipole of the HALL effect probe, directly proportional to the intensity of the current having generated the magnetic field directed on said probe.

Other characteristics and advantages will emerge from the description which follows of embodiments of the device of the invention, description given by way of example only and with reference to the appended drawings in which
- Figure 1 shows the electrical diagram of the
measuring device according to the invention;
- Figure 2 illustrates a first embodiment of the
device of the invention applied to the measurement of
currents flowing in printed circuits, and
- Figure 3 illustrates a second embodiment
applied to the measurement of larger currents
circulating in busbars.

 FIG. 1 represents the basic electrical diagram of the device according to the invention.

 In this figure there is symbolically represented in 1 a HALL effect probe, such as that commercially available under the commercial reference K.S.Y.10 and manufactured by the German company SIEMENS.

 Such a probe consists of a solid component of very small dimensions comprising two electrical dipoles 2 and 3 respectively, equivalent and non-polarized, neither individually nor mutually.

Probe 1 is placed in an electromagnetic field
H generated by the alternating electric current whose intensity we want to measure. In one (2) of the dipoles a continuous control current is circulated by means of a direct current source 4 connected, on the one hand, to a conductor 5 common to the two dipoles and, on the other hand , at the other end of dipole 2, via a resistor 6 for current limitation, in series with an adjustable potentiometric resistor 7, and a switch 8.

 In the presence of the magnetic field H, the switch 8 being closed, the dipole 3 supplies between the terminals 9 and 10 a signal constituted by a voltage U capable of being applied, by means of a connection capacitor 11, to an amplifier (not shown) suitable for the specific use envisaged of said voltage U. The latter, insofar as the control current applied to dipole 1 does not exceed an intensity of 5 A for the type of probe described above , is directly and linearly proportional to the H field and therefore to the intensity of the alternating electric current generating said field.

 In this device, the HALL voltage is directly dependent on the control current supplied by the source 4 and passing through the didipole 2, which makes it possible to measure very high intensities without reaching the voltage limit supplied by the probe, that is to say about 100 mV: it suffices to lower the control current by acting on the adjustable resistor 7.

 The voltage U thus reproduces the periodic variation of the intensity of said current faithfully and with great sensitivity. The consumption of the circuit shown in Figure 1 is also negligible, the control current being very low, of the order of 5 mA, the source 4 being for example a 12-volt battery.

 FIG. 2 illustrates a first embodiment of the device of the invention applied to the measurement of a current flowing in a conductor 12 printed on each face of an insulating substrate 13, for example made of epoxy glass. A simplified magnetic circuit concentrates the magnetic flux through the HALL 1 probe, this circuit comprising two bars of non-permanent magnetic material 14 and 15, for example of soft iron, nickel or ferrite, held parallel to the substrate 13 and pressed against the latter at using a spacer sleeve 16 crossing the substrate and into which is inserted a screw 17 of non-permanent magnetic material ensuring the connection between the bars 14 and 15 and a screw 18 of insulating material, for example polyamide , passing through the substrate as well as the conductors 12. Insulating plates 19 are interposed between the bars 14 and 15 and the substrate 13.

 At the other end of the bars 14 and 15 are arranged opposite two screws of non-permanent magnetic material, respectively 20 and 21, one (20), passing through the substrate, carrying the HALL 1 probe and making it possible to position it at a height, with respect to the substrate 13, authorizing the welding of the probe connections directly on the printed circuit and, the other (21), making it possible to adjust the air gap between the probe 1 and the screw 21 and thus providing an adjustment mechanics of the output voltage U of the device of the invention. The latter is not shown in FIG. 2. It is for example identical to that of FIG. 1 and identically connected to the probe 1.

 The external face of the insulating plates 19 can be coated with a conductive layer connected to the ground and serving as electrostatic shielding.

 Such a mechanical assembly is suitable for currents of the order of 60 A.

 FIG. 3 illustrates an assembly for applying the device of FIG. 1 to the measurement of a current of higher intensity flowing in a conductive bar 22, shown in cross section.

 An U-shaped insulating support 23 surrounds the bar 22 on three sides. The support 23 supports on its three ribs, externally, three pole pieces 24, 25, 26 connected together by screws 27. Two brackets 28 and 29 made of non-permanent magnetic material close the circuit by being fixed by screws 30 to the end of the pieces 24 and 26. An insulating piece 31 is interposed between the ends of the pieces 24 and 26 and forms the fourth rib of the support 23 by being fixed by pins 32 interposed between the pieces 23, 28 and 29.

 Of course, adjustable insulating shims (not shown) are interposed between the bar 22 and the support 23, 31 in order to block the entire device on the bar.

 The part 31 comprises a slide 33 supporting a small printed circuit CI for the electrical connection of the HALL probe 1. The probe 1 is crossed by the magnetic flux conducted by two opposing screws 34 and 35 secured respectively to the brackets 28 and 29. L one (35) of the screws supports the probe 1, while the other (34) allows the adjustment of the air gap between the probe 1 and the screw 34.

 The probe 1 is, as in the case of the assembly of FIG. 2, connected to a circuit as shown in FIG. 1, and generating the voltage U proportional to the intensity of the current flowing in the bar 22.

 It should be noted that the bar 22 can be a solid or flexible laminated bar or be replaced by a cable.

 The device according to the invention can be used according to various applications on printed circuits or on circuits with bar conductors or other crossed by currents of intensity which can be very high, on alternating mono or polyphase networks. Each phase, as well as possibly the neutral, can be provided, according to the envisaged applications, with a device for measuring intensity according to the invention-, the signals coming from these devices being able to be processed - so as for example to detect insulation faults, earth leaks, phase imbalances, etc.

 Of course, the invention is not limited to the embodiments shown and described above, but on the contrary covers all variants thereof, in particular as regards the configuration of the magnetic loop responsible for channeling the magnetic flux generated by the current to be measured on the HALL probe, depending on the nature of the conductor crossed by said current.

Claims (5)

R E V E N D I C A T I O N S: =: =: =: =: =: =: =: =: =: =: =: =: =:  1. Device for measuring the intensity of an alternating electric current, characterized in that it comprises a HALL effect probe (1) consisting of two electric dipoles, one of which (2) is connected to a circuit called control comprising a direct current source (4) and a preferably adjustable electrical resistance (6,7) and the other (3) of which is capable of delivering at its terminals (9,10) a signal in the form of a voltage U, said probe (1) being interposed in a magnetic field (H) generated by the current whose intensity is to be measured.  2. Device according to claim 1, characterized in that said probe (1) is interposed between two pieces of non-permanent magnetic material (20,21,34,35), arranged in opposition on either side of the probe, one of the parts (21,34) being mounted adjustable in distance from the probe, so as to modify the air gap, the two parts being connected by parts made of non-permanent magnetic material  (14,15,17; 24,25,26) so as to form together a magnetic loop surrounding the conductor (12,22) in which the current flows whose intensity is to be measured.  3. Device according to claim 2, characterized in that said conductor is a conductor (12) printed on an insulating substrate (13).  4. Device according to claim 2, characterized in that said conductor is a conductive bar (22) or other conductor capable of conducting currents of intensity which can be very high.  5. Device according to one of claims 2 to 4, characterized in that an electrically insulating material (19; 23,31) is interposed between the conductor and the parts (14,15,16,20,21; 24, 25,26,34,35) forming said magnetic loop.