CH702264A1 - Device for measuring current flowing through current conductor for indicating charging condition of battery, has magnetic element and concentrator with end areas, and shield surrounding concentrator, where end areas overlap with each other - Google Patents

Abstract

The device has a circular concentrator (2) made of ferromagnetic material and extending in a plane running perpendicular to a current conductor (1). A magnetic field sensor (4) has a magnetic element (10) i.e. magneto resistive sensor and flux gate sensor, attached to a semiconductor chip and arranged above or below an air gap (3) of the concentrator for bridging the air gap. Two end areas of the magnetic element and two end areas of the concentrator overlap with each other, respectively, and a shield (5) partially surrounds the concentrator in the plane that is clamped by the concentrator.

Description

The invention relates to a device for current measurement.

In order to display the state of charge of a battery, it is necessary to measure the current flowing during stand-by operation or in the off state and integrate over time. These stand-by currents are very small, typically ranging from 10 to 100 milliamperes. When the battery is charged, then flows of up to 100A, briefly up to 1000A.

From the prior art, a plurality of current sensors or devices for current measurement are known. EP 1 811 311 discloses a current measuring device which is suitable for measuring currents up to typically 100 A, can be loaded for a short time with an overload current of up to 1000 A and is shielded against external magnetic interference fields. CH 696 859 and JP 62 098 267 disclose current sensors in which a first Hall sensor in the air gap of a yoke made of ferromagnetic material is arranged, which surrounds the conductor, and a second Hall sensor is arranged outside the yoke. The yoke and the first Hall sensor are used to measure relatively small currents, the second Hall sensor is used to measure relatively large currents. A disadvantage of these solutions is that the air gap with typically 1-3 mm is relatively large, the yoke requires much material and the production is complicated.

The invention has for its object to develop a device for current measurement, which in continuous operation with a current of up to 100 A, briefly up to 1000A, can be loaded, in which the disadvantages mentioned are eliminated and the simple and material-saving manner can be produced.

The above object is achieved by the features of claim 1. Advantageous embodiments will be apparent from the dependent claims.

The invention will be explained in more detail by means of embodiments and with reference to the drawing. The figures are not drawn to scale. <Tb> FIG. 1 and 2 <sep> show in plan the basic principle of a device according to the invention for current measurement, <Tb> FIG. 3 <sep> shows the device in a section along the line I-I of FIG. 1, <Tb> FIG. 4 <sep> shows a characteristic, and <Tb> FIG. 5 <sep> shows another example of the device according to the invention.

Figs. 1 and 2 illustrate in plan the basic principle of an inventive device for current measurement based on two largely similar embodiments. FIG. 3 shows the basic principle of the device in section along the line SS of FIG. 1. The device comprises a current conductor 1, a ring concentrator 2, a sensor 3, a shield 4 and an electronic circuit (not shown) for the operation of the sensor 3 The current I to be measured flows through the current conductor 1, which runs perpendicular to the plane of the drawing. The ring concentrator 2 is a magnetic concentrator formed of an annular strip of ferromagnetic material whose ends 6 and 7 face each other and are separated by an air gap 5. The shape of the ring concentrator 2 is preferably adapted to the conductor 1, it may be circular, rectangular or arbitrary different. The ring concentrator 2 consists of a Ni-Fe alloy or an amorphous metal and is relatively thin: it has a thickness of at least 20 μm, typically about 100 μm, and a width of typically about 3 to 5 mm, so that it is at a Current I from about 5 to 10 A is already magnetically saturated.

The sensor 3 comprises two magnetic field concentrators 9, 10 separated by an air gap 8 and a magnetic field sensor 11 arranged within or immediately below or above the air gap 8. The sensor 3 is placed in the region of the air gap 5 on the ring concentrator 2, in that an end region of the magnetic field concentrator 9 and an end region at the end 6 of the ring concentrator 2 and an end region of the magnetic field concentrator 10 and an end region at the end 7 of the ring concentrator 2 overlap. The ring concentrator 2 can touch the magnetic field concentrators 9, 10 directly. However, the ring concentrator 2 and the magnetic field concentrators 9, 10 can also be separated from one another by an air gap or a housing wall of the sensor 3. The magnetic field sensor 11 is thus on the one hand inside or immediately below or above the air gap 8 and on the other hand approximately centered below or above the air gap 5 of the ring concentrator 2. The magnetic field sensor 11 is preferably a horizontal Hall element, but it can also be a vertical Hall element or a magnetoresistive element (also known as AMR or GMR). The ring concentrator 2 and the sensor 3 enclose the conductor 1. The conductor 1 extends perpendicular to the plane which is spanned by the ring concentrator 2. The conductor 1 is for example a cable, a pin, a battery terminal, a busbar or the like. The current conductor 1 is not a coil which is wound around the ring concentrator 2.

The magnetic field sensor 11 is advantageously integrated in a semiconductor chip 12 (FIG. 3). The magnetic field concentrators 9, 10 are arranged on the surface of the semiconductor chip 12. The magnetic field concentrators 9, 10 are produced by applying a layer of ferromagnetic material to a not yet sawed wafer with the semiconductor chips 12 and then structuring this layer by means of an etching process. Because the etching mask is aligned with marks of the semiconductor chip 12, the magnetic field concentrators 9, 10 are aligned with very great accuracy with respect to the magnetic field sensor 11. The width of the air gap 8 between the magnetic field concentrators 9, 10 is a few tens of microns, typically about 30 microns. The magnetic field concentrators 9, 10 have a maximum width in the range of about 0.3 mm to 0.8 mm and are preferably tapered towards the air gap 8 out. The ends 6, 7 of the ring concentrator 2 are also advantageously - as shown - tapers.

It is optimal if the ends 6, 7 of the ring concentrator 2 are only slightly wider than the magnetic field concentrators 9, 10, namely so wide that the magnetic field concentrators 9, 10 regardless of unavoidable, lying in the tolerance range assembly errors in any case with the ends 6, 7 of the ring concentrator 2 overlap and do not protrude laterally beyond the ring concentrator 2.

The shield 4 is a strip of ferromagnetic material whose thickness is substantially greater, namely by at least a factor of 5, than the thickness of the ring concentrator 2. In the example, the thickness of the ring concentrator 2 is about 0.1 mm, the thickness of the shield about 1 mm. The shield 4 encloses the ring concentrator 2 on approximately three sides, i. the shield is typically about "U" (Fig. 1) or "C" (Fig. 2) shaped strip. The shield 4 is oriented so that the sensor 3 is in the region of the opening of the "U" or "C". The shield 4 has a main task and an optional additional task. The main task is to shield the magnetic field sensor 11 in the measuring range of small currents against external magnetic fields, which extend in the plane of the ring concentrator 2. This measuring range is the range in which the ring concentrator 2 is not magnetically saturated. This first measuring range extends over a range from 0 A to about I1 with typically I1 ≅ 5 A or I1, ≅ 10 A. When the ring concentrator 2 is magnetically saturated, it no longer amplifies the magnetic field generated by the current I, that is magnetically transparent. The optional additional task of the shielding 4 is to act as a magnetic field concentrator in a second measuring range, which adjoins directly to the first measuring range, and to amplify the magnetic field generated by the current I in the region of the sensor 3, i. In this measuring range, the shield acts together with the magnetic field concentrators 9, 10 as a reinforcing magnetic circuit. In the example, this second measuring range is the range from I to 100 A. The transition from the first measuring range to the second measuring range is fluent and not defined by a sharp limit.

4 shows the characteristic of the magnetic field sensor 11 in function of the current I.

The shield 4 may also be designed so that it only fulfills the main task, namely the shielding of the magnetic field sensor 11 against external magnetic fields. In this case, the shield 4 advantageously encloses the ring concentrator 2 almost completely, i. the air gap 8 is relatively narrow, e.g. only 1 mm wide, as shown in FIG.

The ring concentrator 2 consists of a thin sheet or of a laminate of superimposed thin sheets and is applied to a carrier 13 (Fig. 3). The ring concentrator 2 can also be formed in thick-film technology, for example by electro-plating on the carrier 13. The carrier 13 is for example a ceramic plate or a printed circuit board. The carrier 13 gives the ring concentrator 2 the necessary mechanical stability.

The sensor 3 is advantageously in a standard plastic housing such. a S0-8 housing or in a plastic housing open at the top, e.g. housed in a so-called "open cavity" SO-8 housing. This makes it possible to test the sensor 3 and mount it as a tested component in a standard assembly process. Because the magnetic field concentrators 9, 10 are mounted on the semiconductor chip containing the magnetic field sensor 11, the ring concentrator 2 is advantageously mounted so as to only touch the housing of the sensor 3, but not the magnetic field concentrators 9, 10 itself, to stress-related measurement errors avoid. Depending on the design, the sensor 3 can be mounted on the circuit board with the ring concentrator 2, or it can be the sensor 3 and the carrier 13 are mounted with the ring concentrator 2 on a serving as a base circuit board. Preferably, the ring concentrator 2 is applied to the carrier 13, the sensor 3 is packed in a housing and the ends 6, 7 of the ring concentrator 2 rest on the housing of the sensor 3.

The device advantageously further comprises a coil 16, which can be acted upon by a current, with a plurality of windings, which are wound around the ring concentrator 2. The windings are composed of conductor tracks 17 applied on a printed circuit board (dashed lines) and of bonding wires 18 (solid lines). Instead of the bonding wires 18, it is also possible to use a second printed circuit board which has conductor tracks which correspond to the bonding wires and which are connected to the conductor tracks 17 via so-called bumps.

The coil 16 can be used to in the first measuring range a) calibrate the magnetic field sensor and operate it in the so-called «open loop» mode, or b) operate the magnetic field sensor in the so-called "closed loop" mode.

In the "open loop" mode, the coil 16 is subjected to a calibration or a recalibration of the magnetic field sensor 11 at any time with a predetermined calibration current. During the measuring operation, no current flows through the coil 16. The measuring signal in this case is the output signal of the magnetic field sensor 11.

In the "closed loop" mode, the coil 16 is acted upon during the measuring operation with a current K (t), which generates a magnetic field in the air gap 8, which is opposite to the magnetic field generated by the current I (t) to be measured, where the parameter t denotes the time. In this mode, the electronic circuit regulates the current K (t) so that the output signal of the magnetic field sensor 11 always has the value 0. The measuring signal in this case is the current K (t).

The inventive device for current measurement can be combined with a device designed for the measurement of even larger currents device, for example, with a device described in EP 1 811 311, wherein the current conductor is advantageously a common rail bus device.

The device according to the invention has several advantages: - The magnetic resistance of the magnetic circuit formed by the ring concentrator 2 and the sensor 3 is very low, since it has only an air gap of about 30 microns when using a Hall sensor as a magnetic field sensor 11. When using a magnetoresistive sensor as a magnetic field sensor 11, the magnetic resistance is even lower, since the magnetoresistive sensor itself comprises ferromagnetic layers, so that the effective air gap of the magnetic circuit is even smaller or disappears. This results in a high sensitivity of the device. - The current that must flow through the coil 16 in the "closed loop" mode to compensate for the magnetic field generated by the current I to be measured, is much smaller than in the prior art. - The cost of materials is less than in the prior art. The device is based on planar technology processes with their advantages.

Claims (4)

1. Device for measuring a current flowing through a current conductor (1), comprising a ring concentrator (2) of ferromagnetic material having two opposite ends (6, 7) separated by a first air gap (5), a sensor (3) having two magnetic field concentrators (9, 10) separated by a second air gap (8) and a magnetic field sensor (11) arranged in the region of the second air gap (8), one end region of the one magnetic field concentrator (9) and one end region at overlapping one end (6) of the ring concentrator (2) and an end portion of the other magnetic field concentrator (10) and an end portion at the other end (7) of the ring concentrator (2), and a shield (4), the ring concentrator (2) and the magnetic field concentrators (9, 10) forming a magnetic circuit enclosing the conductor (1), and the shield (4) surrounding the ring concentrator (2) through the ring concentrator (2) partially encloses the spanned level. 2. Apparatus according to claim 1, characterized in that the shield (4) completely encloses the ring concentrator (2) in said plane with the exception of a narrow air gap. 3. A device according to claim 1, characterized in that the shield (4) is "U" -shaped or "C" -shaped. 4. Device according to one of claims 1 to 3, characterized in that the ring concentrator (2) on a support (13) is applied, that the sensor (3) is packed in a housing and that the ends (6, 7) of the Ring concentrator (2) resting on the housing of the sensor (3).