LU102798B1 - Current measuring system for measuring a current flowing through an electrical current conductor and a corresponding method - Google Patents

Abstract

The invention relates to a current measuring system (1) for measuring, in particular indirect measuring, a current flowing through an electrical current conductor (2), comprising: a magnet core (4) which has a through opening (6) and has a maximum cross-sectional area (8), - wherein the magnetic core (4) is separated at one point to form an air gap (10) and two, in particular opposite, cross-sectional areas (12a, 12b) of the magnetic core (4) are exposed there to delimit this air gap (10), - wherein the magnetic core at least one sensor (14) is mounted and arranged in the air gap (10) in the correct position, specifically for measuring a current (2) that is fed through the through-opening (6) and the current (Ip) flowing through it that occurs in the magnet core (4). magnetic flux (<t>), and - the exposed cross-sectional areas (12a, 12b) are each smaller than the maximum cross-sectional area (8) and the transition between the maximum alen cross-sectional area (8) and each of the two exposed cross-sectional areas (12a, 12b), in particular for the concentration of the magnetic flux and the resulting increase in the flux density, is designed to be fluent, in particular continuously fluent.

Description

The invention relates to a current measuring system for measuring a current flowing through an electrical conductor and a corresponding method.

Current measuring systems for measuring a current flowing through an electrical current conductor are known from the prior art, in which the current-carrying conductor is guided through the opening of a magnet core for this purpose. In this way, the magnetic field that forms around this current-carrying conductor can be bundled in the magnetic core, which in particular also serves as a field concentrator, and used to determine the current flowing through the conductor, i.e. in particular to determine the current strength, the flowing magnetic flux that occurs in the core and conventionally converted back into an electrical signal In order to be able to record the electrical flow in the magnetic core, it is separated at one point and such. an air gap is formed at this point, into which a sensor for detecting the magnetic flux is inserted, which detects the magnetic flux and generates a corresponding electrical output signal. The sensor, in particular a Hall sensor, acts together with the magnetic core when measuring the current as a kind of measuring transducer. Such a current measuring system is also often used as part of a current measurement known as an open-loop measurement, in which a voltage proportional to the magnetic field strength in the air gap of a magnetic core, usually initially small, is generated in the sensor, this is then amplified and the amplified voltage is then generated represents the output signal of the sensor. The advantages are a very low power consumption and the compact design, the disadvantages are the often only moderate bandwidth and high rise time.

An imaging error and especially its temperature dependency is often problematic. Over a wide range of application temperatures, such as from -25 to +85 °C, the error can even be in the double-digit percentage range. Open-loop sensors are therefore usually suitable for less demanding applications. Even the smallest changes in relation to the air gap, even in the µm range, can affect the current measurement and its accuracy.

For example, hysteresis effects occur during the magnetization of an iron core and thus during the production of the magnetic core. If an electric current is passed through the current conductor, which is fed through an iron core that has not yet been magnetized, the core becomes magnetized. In this magnetization phase, both the magnetic field strength H and initially the flux density B increase, with the magnetic flux ® detected by a sensor in an air gap as described above ultimately depending on the field lines running essentially perpendicular to the cross-sectional area at this point. The greater their density B, the greater the detected magnetic flux ® at this point. With a further increase in the electric current and thus also in the magnetic field strength, the increase in the magnetic flux density gradually stagnates and the core gets into the saturation range, which leads to non-linearity and then hardly leads to a significant increase in the flux density B. However, if the current strength is reduced back to the value zero and consequently also the resulting magnetic field strength, the flux density only drops to the value of a material-specific remanence flux density, which is inherent to all ferromagnetic materials. Only when the respective negative coercive field strength is undershot does the flux density also assume negative values, up to the point of renewed saturation. If the current intensity is increased again to the value zero, the flux density increases again initially only up to the (negative) remanence flux density and only when the respective positive coercive field strength is exceeded as a result of a further increase in current does the flux density also assume positive values again, until the saturation range is reached again is.

Because of the resulting hysteresis, magnetic materials with a low coercive field strength are generally used in areas where there is frequent magnetization reversal, such as in the case of inductive current measuring transducers, in order to keep the hysteresis effects as low as possible. On the other hand, it must always be ensured that a magnetic core used for current measurement, e.g. as a field concentrator in a transmitter, is only used in the linear range of the hysteresis curve, since operation in the saturation range can lead to large measurement errors.

From the publication DE 11 2014 001 216 T5 a sensor for measuring the electric current is known, which has a magnetic core with a connecting portion formed by bending a part of a plate member. Both end portions of the plate member are arranged opposite each other and form a constant magnetic gap between them, within which a Hall sensor for detecting a generated magnetic flux is arranged. The end sections between which the gap is formed taper in width, starting from the connecting section, in each case adjacent to the other end section to their distal end in such a way that there is no place between the connecting section and each distal end where a magnetic field is concentrated and the Core thereby has a uniform magnetic reluctance characteristic. The publication EP 1 811 311 B1 also describes a device for measuring current with a magnet core which forms a through opening through which a current conductor is routed. For this purpose, the magnetic core is formed from an elongated piece of sheet metal and bent accordingly, with two side walls facing one another being separated by an air gap. A magnetic field sensor is arranged inside the through hole and outside the air gap.

The publication JP 2009-300196 A also discloses a current measuring system with a substantially rectangular magnetic core forming a through hole through which a current conductor can be passed. The magnetic core is also separated to form an air gap. The magnetic core is mounted together with a Hall element in a housing accommodating them, the Hall element being mounted on the housing in such a way that it can be positioned within the air gap. The two ends delimiting the gap each have converging sections that taper towards the middle of the gap, so that the magnetic flux can basically be concentrated in the direction of the gap. However, the transitions to tapered or tapering sections are each formed by sharp shoulders, which makes it difficult to focus the magnetic field lines and thus to increase the flux density. Furthermore, mounting the Hall element on the housing in many industrial fields with harsh environmental conditions does not guarantee permanent position-accurate mounting within the air gap and can consequently contribute to further measurement errors.

A similar arrangement is known from JP 2011-99751 A. For a current measuring system with a C-shaped magnetic core forming a through-opening, a circuit board with a Hall sensor mounted on it is placed between the open ends. Further embodiments, in each of which a magnetic field sensor is fixed outside a magnetic core and is kept aligned in the middle of a gap provided by cutting the metal core, can be found, for example, in JP 2012-37377 A, JP002013134076A and WO 00/37948.

The invention is based on the object of demonstrating a current measuring system that is improved compared to the prior art, which is also particularly suitable for rough industrial field conditions and provides a more homogeneous and concentrated areal density of the magnetic flux in the air gap of the magnetic core, in particular in the area of a sensor arranged in the air gap. so that even if saturation effects occur in the core material, a signal deflection caused proportional to the magnetic field strength in the air gap and thus the signal integrity of the sensor is improved overall and the current measuring system continues to have high measuring accuracy.

The invention proposes a current measuring system according to the features of claim 1 and a method according to claim 9 as a solution. Expedient developments are the subject of the respective subclaims.

Accordingly, the invention proposes a method for measuring, in particular for indirect measurement, a current flowing through an electric current conductor, in which the current conductor is guided through a through-opening in a magnet core and a magnetic flux is subsequently established in the magnet core, with the magnet core Formation of an air gap at one point, at least one sensor, in particular a Hall sensor, is mounted on the magnet core to measure the magnetic flux and is positioned in this air gap with the correct position, and the signal deflection of the sensor is amplified by a guided through the sensor Proportion of the magnetic flux is increased with a simultaneous increase in the flux density through a flowing tapering of the magnetic core cross-sectional area towards the air gap.

Accordingly, in particular for the implementation of the above method, a current measuring system for measuring a current flowing through an electric current conductor is also provided, which has a magnet core which has a through-opening 5 and has a maximum cross-sectional area.

The current measurement system is | designed in particular for the indirect measurement of the current.

For the measurement, the electrical current conductor must be guided through the through hole.

The magnetic core, in particular a magnetic core with a substantially ring-shaped

Structure is separated at one point to form an air gap, so that there are exposed two, in particular opposite cross-sectional areas of the magnetic core to limit this air gap.

The cross-sectional areas are thus preferably aligned parallel to one another.

The magnetic field generated thus exits at one of the cross-sectional areas delimiting the air gap, flows through the

air gap and re-enters the magnetic core at the other cross-sectional area delimiting the air gap.

At least one sensor, in particular a Hall sensor, is also mounted on the magnet core and is positioned in the air gap to measure a magnetic flux that is established in the magnet core when the current conductor is guided through the through-opening and that current flows through it.

A voltage that is generated particularly proportionally in the sensor, and is usually initially small, consequently serves as a measure of the current flow conducted in the current conductor and can then be connected or connected to the sensor for further evaluation

Processing unit are transmitted.

For the position-accurate arrangement in the air gap, the sensor is expediently mounted directly on one of the two exposed cross-sectional areas or also on these two cross-sectional areas, preferably glued, in particular due to the simplicity.

However, casting or caulking for permanently position-accurate assembly is also possible, for example, within the scope of the invention.

According to the invention, the cross-sectional areas exposed to limit the air gap are each smaller than the maximum cross-sectional area of the

Magnetic core and the transition between the maximum cross-sectional area and each of the exposed cross-sectional areas, i.e. the transition of the magnetic core contour, is designed to be fluid, in particular continuously fluid, i.e. free of any discontinuities and steps in the magnetic core contour between the maximum cross-sectional area and each of the exposed cross-sectional areas.

With such a smooth design of the cross-sectional area transition, the magnetic flux in particular can be significantly concentrated and thus also an increase in the flux density can be brought about of the air gap can be reduced to a minimum and an extremely homogeneous magnetic field with a significantly increased magnetic flux flows through the air gap and consequently also the sensor.

This also increases the deflection and increases the integrity of the sensor signal. This in turn has an advantageous effect on the immunity to interference from external fields and at the same time has a positive effect on the SNR (signal-to-noise ratio) due to the increase in the signal amplitude. The measurement of the magnetic field by the sensor mounted in the correct position on the magnetic core is therefore more accurate overall and therefore less error-prone than with comparable current measuring systems of the prior art, since the magnetic flux is always guided to the sensor in a targeted manner, even in a harsh industrial field environment, i.e. even with vibrations, and therefore always the greatest possible flux density is supplied by the sensor.

The contour of the taper in relation to the exposed cross-sectional areas is advantageously adapted to the contour, i.e. in particular the cross-section, of the sensor in order to achieve maximum amplification of the air gap. For this purpose, it has additionally or alternatively proven to be extremely effective if the sensor is arranged centrally on at least one of the two exposed, in particular opposite, cross-sectional areas. In addition or as an alternative, it has also been shown that the targeted guidance of the magnetic flux is optimized if the magnetic core has a contour in which the cross-sectional area in the transition between the maximum cross-sectional area and each of the two exposed, in particular opposite, cross-sectional areas asymptotically approaches the contour of the sensor .

In a particularly preferred embodiment, the magnet core therefore has an essentially ring-shaped structure in which the center points of all cross-sectional areas are essentially always on the same radius at the transition between the maximum cross-sectional area and each of the two exposed, in particular opposite, cross-sectional areas. During the transition, the contour of the magnetic core approaches the same radius in the cross section, coming from all sides.

In the following, the invention will be explained in more detail by means of some preferred embodiments in connection with the accompanying drawings, from which these and other features and advantages of the solution according to the invention will become apparent.

1 shows a schematic basic sketch of a current measuring system according to the invention; 2 is a more detailed cross-sectional view of a tapered magnetic core with a sensor mounted thereon as part of a current sensing system in accordance with the present invention; and FIG. 3 shows another basic sketch, seen from the air gap of the tapering magnetic core of the current measuring system according to the invention, with maximum cross-sectional area of the magnetic core and tapered cross-sectional area at the air gap and with a sensor mounted on the magnetic core.

1 first shows a schematic basic sketch of a current measuring system according to the invention for measuring, in particular indirect measuring, a current Ip flowing through an electric current conductor 2 .

It goes without saying that the current conductor 2 must first be connected to a corresponding electronic device in order to generate a current flow, which, however, is not shown in FIG. 1 for reasons of clarity.

As can be seen in FIG. 1, the outlined current measuring device comprises a magnetic core 4 which has a through opening 6 through which the current-carrying conductor 2 is to be guided for measuring the current flow and which has already been guided through this in FIG. The magnetic core has in the shown ZELL.

Embodiment, a substantially ring-shaped structure and is thus suitably designed as a toroidal core. Furthermore, the magnetic core 4 is separated at at least one point to form an air gap. A sensor 14, in particular a Hall sensor, is arranged in the correct position in this air gap, it also being possible for several sensors to be arranged in the correct position in such an air gap 10, depending on the specific design. Each sensor 14 is used here to measure a magnetic flux ® occurring in the magnetic core 410 when the current conductor 2 is guided through the through-opening 6 with current Ip flowing through it. Due to the separation of the magnetic core to form at least one air gap, however, other magnetic core shapes can also be used, in particular depending on the specific design, such as, for example, similar to a "C core" or a "U core", which already have a , having an air gap forming severed point per se. However, a “toroidal core” has proven to be particularly preferred, since the magnetic core can advantageously bundle the magnetic field that forms around the current-carrying conductor 2 and can thus also serve as a kind of field concentrator.

The magnetic core 4 basically has a maximum cross-sectional area 8, wherein according to FIG. According to the invention, these exposed cross-sectional areas 12a, 12b are each smaller than the maximum cross-sectional area 8, as can be seen in particular in FIGS. 2 and 3 can be clearly seen and based on these Figs. will be described in more detail. Here, the transition between the maximum cross-sectional area 8 and each of the two exposed, in particular opposite, cross-sectional areas 12a, 12b is designed to be fluid, in particular continuously fluid. In particular, this results in a tapering of the outer contour of the magnetic core 4 or such a smooth transition 4 can be created by suitable tapering of the outer contour of the magnetic core 4 . As a result, the magnetic flux ® can be concentrated in an expedient manner, which in particular in the direction of the exposed cross-sectional areas 12a, 12b, which are smaller in relation to the maximum cross-sectional area 8, thus also causes an increase in the flux density.

Furthermore, in order to position each sensor 14 in a position-accurate manner, and in particular to position it in a position-accurate manner independently of any environmental influences, this sensor 14 is also mounted on the magnetic core. Consequently, for example, any vibration exerted on the magnetic core also has a direct effect on the sensor 14, so that an otherwise possible relative position shift by means of mounting on the magnetic core is effectively avoided, in particular completely ruled out. The assembly of the sensor 14 on the magnet core 4 can be carried out expediently on at least one of the two exposed cross-sectional areas 12a, 12b delimiting the air gap 10, with gluing in particular having been shown to be particularly practicable in order to create a permanently fixed connection directly between the sensor 14 and the magnet core 4 to effect. As a result of mounting on at least one of the cross-sectional areas 12a, 12b, distances to be bridged for an arrangement in the air gap 10 can also be minimized, which also contributes to a permanently stable, position-accurate position, which can otherwise adversely affect the measurement accuracy. However, other types of assembly, such as casting or caulking, are also possible within the scope of the invention. As also outlined in FIG. 1, the sensor 14, or also several sensors as described above, can be connected to a correspondingly suitably set up processing unit 18, in particular for a subsequent further evaluation. Such an evaluation can be carried out, for example, in the device labeled “uC” in FIG. 1, ie in particular a device comprising a microcontroller, of the processing unit 18. A signal output by the sensor, in response to the magnetic flux ® flowing through the air gap and consequently also through the sensor, can first be e.g. amplified and/or subjected to an analog-to-digital conversion, as in FIG. 1 e.g. by the unit designated ADC reproduced, so that further evaluation can be carried out digitally. In this case in particular, a digital-to-analog conversion can be carried out again, for example, as in FIG.

represented by the unit labeled DAC. The analog signal is then provided, for example, as an output signal of the processing unit 18 at an output port. 2 shows a schematic but more detailed cross-sectional view of the tapering magnetic core 4 with a sensor 14 mounted thereon within the framework of a current measuring system 1 according to the invention. Again, it can be seen that the magnetic core 4 basically has a maximum cross-sectional area. The air gap 10, in which the sensor 14 is arranged in the correct position, is formed by the two cross-sectional areas 12a and 12b of the magnet core. A fastening means for mounting the sensor on the magnetic core, in the present example on the cross-sectional area 12b, is identified by reference number 30 . In the exemplary embodiment shown, the fastening means is expediently an adhesive or glue. A voltage generated by the sensor 14 as a function of the magnetic flux D flowing through the air gap is indicated by U.u.

The magnetic core 4 is expediently a toroidal core and the current conductor 2 is preferably guided centrally through the through-opening 6 of the magnetic core 4 . Points within the magnet core 4 lying on the same, i.e. common, radius R are also indicated by means of the dot-dash line.

The smooth transition between the maximum cross-sectional area 8 and each of the two exposed cross-sectional areas 12a and 12b delimiting the air gap 10 is shown in Fig. 2 by the dashed lines that converge in a tapered manner represent "new" core contour of the magnetic core 4. The taper thus runs, starting from the maximum cross-sectional area 8, in the direction of the respective cross-sectional areas 12a and 12b of the air gap 10. Another basic sketch, viewed from the air gap of the tapering magnetic core, in particular in the direction of the arrow assigned to the voltage Uout according to FIG. 2 , is shown in FIG. 3, a maximum cross-sectional area 8 of the magnetic core 4, an exposed, tapered cross-sectional area 12a at the air gap and a sensor 14 mounted on the magnetic core being shown in a highly schematic manner as an example.

In particular, Figs. 2 and 3 that the contour of the two exposed cross-sectional areas 12a and 12b is appropriately adapted to the contour of the sensor 14 following. As can be seen, the magnet core 4 also has a contour in an expedient configuration, i.e. a resulting “new” core contour in which the cross-sectional area changes in the transition between the maximum

Cross-sectional area 8 and each of the two exposed cross-sectional areas 12a and 12b asymptotically approximates the contour of the sensor. The size and shape of the cross-sectional areas thus preferably taper in such a way that the size and shape of each of the cross-sectional areas 12a and 12b at the air gap essentially correspond to the size of the shape of the cross-sectional area of the contour of the sensor 14, so that the appropriate entire, at least approximately entire, the cross-sectional areas 12a and 12b and consequently the magnetic flux flowing through the air gap also flows through the sensor 14 . In this way, the magnetic flux density can be concentrated or focused on the sensor 14 in a particularly advantageous manner, so that a magnetic field emanating from the magnetic core and maximally amplified in relation to the sensor 14 acts on the latter.

The transition between the maximum cross-sectional area 8 of the magnetic core 4 and each of the two exposed cross-sectional areas 12a, 12b is therefore preferably designed to be exclusively fluid, i.e. without jumps and steps.

In particular, the flatter the transition between the maximum cross-sectional area 8 of the magnetic core 4 and each of the two exposed, in particular opposite, cross-sectional areas 12a, 12b, the lower the stray field propagation in the area of the air gap 10 can be kept. On the other hand, as a result, the homogeneous magnetic field in the air gap 10 can advantageously be increased all the more, as a result of which the measurement of the sensor 14 becomes more accurate overall and thus less error-prone. The measuring accuracy of the sensor 14 can therefore be maximized in particular by the resulting increase in the signal deflection or amplitude in relation to the signal output by the sensor. This in turn leads to further advantages, also with regard to immunity to interference from external fields and a positive effect on a significantly improved signal-to-noise ratio.

For an optimal adaptation of the contour with a correspondingly flowing tapering of the cross-sectional area of the magnet core, in particular for providing the greatest possible flux density through the sensor 14, the sensor 14 is thus expediently arranged centrally on at least one of the two exposed, in particular opposite, cross-sectional areas 12a, 12b (cf 3) and/or is the contour adjustment such that the center points of all cross-sectional areas at

Transition between the maximum cross-sectional area 8 and each of the two exposed cross-sectional areas 12a, 12b are essentially always on the same radius R (see FIG. 2).

Taking into account the above description, it can consequently be stated in summary that, according to the solution of the invention, the geometry of the cross section of the magnet core 4 in the direction of the air gap 10 is approximated to the cross section of the sensor 14 . Since the magnetic field of the flux density B in the material is advantageously increased with a correspondingly adapted reduction in the cross-sectional area through which the magnetic flux flows in the region of the air gap 10, this property allows the field to be increased by a core tapering immediately before the exit and entry at the air gap and adjusted accordingly in relation to the sensor 14, i.e. in particular to optimize the measurement result.

Consequently, to measure a current flowing through an electrical conductor, a magnetic core 4 with a through opening 6 is separated at one point to form an air gap 10 and at least one sensor 14, in particular a Hall sensor, is mounted on the magnetic core and positioned correctly to measure a magnetic flux ® arranged in this air gap 10, after the current conductor 2 has been routed through the through-opening 6 and, with the current Ip then flowing, a magnetic flux ® is set in the magnet core 4 as a result, the signal deflection of the sensor can be amplified by the through the Sensor-guided part of the magnetic flux ® is increased with a simultaneous increase in flux density through a flowing tapering of the magnetic core cross-sectional area towards the air gap.

As a result, within the scope of the invention, a significantly improved B field distribution in the air gap 10 can be achieved and the sensor arranged in this and attached to the magnet core can be subjected to a relatively large B field, even if the core material has a hysteresis characteristic in some areas already showing saturation effects. The sensor, in particular a Hall sensor, can therefore advantageously be operated in a large modulation range and the deflection and thus the signal integrity can be significantly improved.

CELL

Claims (9)

Claims 1) Current measuring system (1) for measuring, in particular indirect measuring, a current flowing through an electric current conductor (2), comprising: a magnetic core (4) which has a through opening (6) and has a maximum cross-sectional area (8), - wherein the magnetic core (4) is separated at one point to form an air gap (10) and two, in particular opposite, cross-sectional areas (12a, 12b) of the magnetic core (4) are exposed there to delimit this air gap (10), - wherein the magnetic core at least one sensor (14) is mounted and arranged in the air gap (10) in the correct position, specifically for measuring a current (2) that is fed through the through-opening (6) and the current (Ip) flowing through it that occurs in the magnet core (4). magnetic flux (®), and - wherein the exposed cross-sectional areas (12a, 12b) are each smaller than the maximum cross-sectional area (8) and the transition between the maximum transverse cut surface (8) and each of the two exposed cross-sectional surfaces (12a, 12b), in particular for the concentration of the magnetic flux and the resulting increase in the flux density, is designed to be fluent, in particular continuously fluent. 2) current measuring system (1) according to claim 1, characterized in that the sensor (14) for position-accurate arrangement in the air gap (10) is mounted on at least one of the two exposed cross-sectional areas (12a, 12b), in particular is glued. 3) current measuring system (1) according to claim 1 or claim 2, characterized in that the sensor (14) is arranged centrally on at least one of the two exposed, opposite cross-sectional areas (12a, 12b). 4) current measuring system (1) according to any one of the preceding claims, characterized in that the contour of the two exposed cross-sectional areas (12a, 12b) of the contour of the sensor (14) is adapted to follow. 5) current measuring system (1) according to any one of the preceding claims, characterized in that the magnetic core (4) has a contour in which the Cross-sectional area in the transition between the maximum cross-sectional area (8) and each of the two exposed cross-sectional areas (12a, 12b) asymptotically approximates the contour of the sensor (14). 6) current measuring system (1) according to any one of the preceding claims, characterized in that the magnetic core (4) has a substantially ring-shaped structure and the centers of all cross-sectional areas at the transition between the maximum cross-sectional area (8) and each of the two exposed cross-sectional areas (12a, 12b) essentially always lie on the same radius. 7) Current measuring system (1) according to any one of the preceding claims, further characterized by a processing unit (18) connected to the at least one sensor (14). 8) current measuring system (1) according to any one of the preceding claims, characterized in that the sensor (14) is a Hall sensor. 9) Method for measuring, in particular for indirect measuring, a current flowing through an electrical current conductor (2), in which the current conductor (2) is passed through a through-opening (6) of a magnetic core (4) and a magnetic flux is consequently generated (®) in the magnetic core (4), the magnetic core (4) being separated at one point to form an air gap (10), at least one sensor (14), in particular a Hall sensor, for measuring the magnetic flux (®) mounted on the magnetic core and arranged in the correct position in this air gap (10), and the signal deflection of the sensor is amplified by a portion of the magnetic flux guided through the sensor while at the same time increasing the flux density through a flowing tapering of the cross-sectional area of the magnetic core towards the air gap is increased.