DE102015006051A1 - ground strap - Google Patents

Abstract

Ground strap having a first terminal contact and a second terminal contact, wherein the first terminal contact with a negative terminal of a battery and the second terminal contact is connected to a ground point, and between the first terminal contact and the second terminal contact a flat band-shaped line section is formed and the line section respectively is connected directly to the two terminal contacts and has a length L and a width B and a thickness D, wherein the thickness D is at most a quarter of the width B and the length L is at least 5 cm. On the line section, a magnetic field measuring device is non-positively connected, wherein the magnetic field measuring device is at least one tenth of the length L of the two terminals removed. The magnetic field measuring device comprises a magnetic field sensor and an evaluation circuit and an interface terminal, wherein the interface terminal has a supply voltage contact and a reference potential contact and a signal terminal. The size of the magnetic field sensor is smaller than a quarter of the width B of the lead portion, and the magnetic field sensor is disposed at least one-fifth of the width B of one of the outer edges of the lead portion. The magnetic field measuring device is set up to output an output signal dependent on the size of a magnetic field acting on the magnetic field sensor on the signal connection as a measure of the current flowing through the line section.

Description

The invention relates to a ground strap according to the preamble of claim 1.

From the DE 10 2011 118 932 A1 For example, a ground strap having a monitoring system with a current sensor is known.

Against this background, the object of the invention is to provide a device which further develops the prior art.

The object is achieved by a ground strap having the features of patent claim 1. Advantageous embodiments of the invention are the subject of dependent claims.

According to the subject invention, a ground strap having a first terminal contact and a second terminal contact is provided, wherein the first terminal contact is connected to a negative terminal of a battery and the second terminal contact to a ground point, and between the first terminal contact and the second terminal contact flat band-shaped line section is formed and the line section is respectively connected directly to the two terminals and a length L and a width B and a thickness D, wherein the thickness D is at most a quarter of the width B and the length L at least 5 cm, or preferably at least 10 cm. On the line section, a magnetic field measuring device is non-positively connected to the line section, wherein the magnetic field measuring device is at least one tenth of the length L away from the two connection contacts. The magnetic field measuring device comprises a magnetic field sensor and an evaluation circuit and an interface terminal, wherein the interface terminal has a supply voltage contact and a reference potential contact and a signal terminal. The size of the magnetic field sensor is smaller than a quarter of the width B of the lead portion, and the magnetic field sensor is disposed at least one-fifth of the width B of one of the outer edges of the lead portion. The magnetic field measuring device is set up to output an output signal dependent on the size of a magnetic field acting on the magnetic field sensor on the signal connection as a measure of the current flowing through the line section.

It is understood that the magnetic field sensor is arranged on the ground strap in such a way that the magnetic field of the current in the line section is measured. In other words, the current flows under the magnetic field sensor. Furthermore, it should be noted that the magnetic field sensor is preferably arranged in the middle with respect to the width of the line section and the line section is generally constructed from a mesh of copper wires. Preferably, the ground strap in the car or truck is used for connection from the negative pole of the battery to the body. It should be noted that in an alternative embodiment, a ferromagnetic conductor material can also be used for the line section or the line section comprises such a material in order to generate a magnetic field. Such an arrangement corresponds to a so-called "back bias" magnet arrangement.

An advantage is that by means of the arrangement of the magnetic sensor directly on the line piece in a simple and reliable way to determine the current in the ground strap. Although current measurements with magnetic field sensors have long been known, however, despite some general indications, the expert has hitherto assumed that only impermissible current intensity determinations can be carried out with magnetic field sensors in grounding straps. Shunt resistors are generally used in particular in the case of currents in the ampere range.

Investigations have shown, however, that in a surprising manner with a present inventive arrangement of magnetic field sensors on the line section, the currents in the ampere range can be determined reproducibly and accurately. The advantage for this is that the line section is designed as a flat band. Only then can the magnetic field sensor be placed so favorably that sufficient accuracy is achieved.

In a further development, the magnetic field measuring device comprises two magnetic field sensors each having a different sensitivity range. As a result, small currents up to 5 A as well as high currents up to 100 A, or preferably up to a few kA, can be reliably measured with high accuracy. If a plurality of magnetic field sensors with different current measuring ranges are arranged on the line section, it is advantageous to arrange the magnetic field sensors either one behind the other in the direction of the longitudinal extent of the line section in the middle or to arrange them transversely to the longitudinal extent directly adjacent to the middle of the line section.

In one embodiment, the magnetic field measuring device is attached to the line section by means of an adhesive connection frictionally. In an alternative embodiment, the measuring device is non-positively connected to the line section by means of a fastening device.

Preferably, the magnetic field sensor and the evaluation circuit are monolithically integrated in a semiconductor body. In one development, the magnetic field measuring device comprises a flux concentrator, wherein the flux concentrator has a plate-shaped, dovetail-shaped form. In this case, the flux concentrator has a small end face and a large end face. The small face is located immediately adjacent to the magnetic field sensor to provide the maximum magnetic flux to the magnetic field sensor. It is advantageous if the small end face of the flux concentrator essentially corresponds to the size of the magnetic field sensor. In a further development, a flux concentrator is arranged on each side of the magnetic field sensor.

In another embodiment, the magnetic field measuring device comprises a Hall sensor designed as a Hall plate. Preferably, the Hall plate is perpendicular to the line section, wherein the main extension direction of the Hall plate is parallel to the outer edge of the line section.

In another development, the magnetic field sensor comprises a threshold value switch or is designed as a threshold value switch. In an alternative, when a threshold value is exceeded, the flow of current in the line section is interrupted. In another embodiment, the magnetic field sensor is designed as a switch and, when a threshold value is exceeded, transmits a signal for disconnecting one of the connection contacts from the negative pole or from the ground point.

Investigations have shown that after applying the magnetic field sensors to the line section, the magnetic field measuring device is calibrated as a whole. As a result, the measurement accuracy of the device can be increased.

The invention will be explained in more detail with reference to the drawings. Here similar parts are labeled with identical names. The illustrated embodiments are highly schematic, d. H. the distances and the lateral and the vertical extensions are not to scale and, unless stated otherwise, also have no derivable geometrical relations to one another. It shows:

1 a view of a first embodiment according to the invention of a ground strap with a magnetic field sensor,

2 a cross-sectional view along the line AA 'on the embodiment shown in the 1 .

3a a curve of the Hall voltage over the current up to a maximum of 5 A,

3b a curve of the Hall voltage over the current up to the kA range

4 a view of a second embodiment with flux concentrators.

The picture of the 1 shows a view of a first embodiment of a ground strap according to the invention 10 with a magnetic field measuring device 20 , The earth band 10 has a first connection contact 30 and a second terminal contact 40 on. The first connection contact 30 is with one negative terminal of a battery and the second connection contact 40 is connected to a ground point - not shown in each case. Between the first connection contact 30 and the second terminal contact 40 is a flat band-shaped line section 50 educated. The pipe section 50 is in each case directly with the two connection contacts 30 and 40 connected and has a length L and a width B and a thickness D. The thickness D is in the 2 shown. The length L is at least 10 cm.

On the band-shaped line section 50 is the magnetic field measuring device 20 frictionally with the line section 50 connected. The magnetic field measuring device 20 is at least one tenth of the length L of the two terminals 30 and 40 removed and has a magnetic field sensor 60 and an evaluation circuit, not shown on. Next to the magnetic field sensor 60 is another magnetic field sensor 65 arranged with another measuring range. Preferably, both magnetic field sensors are designed as Hall plates. Furthermore, the magnetic field measuring device comprises 20 an interface connection 80 , The interface connector 80 has a supply voltage contact VDD and a reference potential contact GND and a signal terminal OUT. The magnetic field sensors 60 and 65 are between the two outer edges 90 of the line section 50 arranged in the middle.

The size of the magnetic field sensor 60 is less than a quarter of the width B of the line section 20 , Also, the magnetic field sensor is at least one fifth of the width B of both outer edges 90 of the line section 20 arranged. The magnetic field measuring device 20 is set up, one the size of one on the magnetic field sensor 60 acting magnetic field dependent output signal VOUT at the signal terminal OUT as a measure of the through the line section 20 to output flowing current I.

In the picture of the 2 is a cross-sectional view along the line AA 'on the embodiment shown in the 1 displayed. The following are just the differences from the illustration of 1 explained. The thickness D is at most a quarter of the width B. It can be seen that the two magnetic field sensors designed as Hall plates 60 and 65 next to each other vertically, so standing, are arranged.

The picture of the 3a and 3b show a course of the Hall voltage VOUT over that in the line section 20 flowing current up to 5 A of the magnetic field sensor 60 or a profile of the Hall voltage VOUT over the in the line section 20 flowing current up to 100 A or up to a few 1000 A of the further magnetic field sensor 65 , Both curves show a linear curve of the Hall voltage across the current, so that very large current ranges can be measured with high precision.

In the picture of the 4 is a view of a second embodiment of the magnetic field measuring device 20 comprising a flux concentrator 100 and another flux concentrator 110 shown. The following are just the differences from the illustration of 1 explained. In this case, the magnetic field measuring device comprises 20 only a magnetic field sensor 60 , The river concentrators 100 and 110 each have a plate-shaped, dovetail-shaped shape with a small end face and a large end face. The small end face is in each case immediately adjacent to the magnetic field sensor 60 arranged. Furthermore, the small face of the flux concentrators 100 and 110 essentially the size of the magnetic field sensor 60 on.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011118932 A1 [0002]

Claims (14)

Ground strap ( 10 ) with a first connection contact ( 30 ) and a second connection contact ( 40 ), wherein the first connection contact ( 30 ) with one negative pole of a battery and the second connection contact ( 40 ) is connected to a ground point, and between the first terminal contact ( 30 ) and the second terminal contact ( 40 ) a flat band-shaped line section ( 50 ) is formed and the line section ( 50 ) each directly with the two terminals ( 30 . 40 ) and has a length L and a width B and a thickness D, wherein the thickness D is at most a quarter of the width B and the length L is at least 5 cm, characterized in that a magnetic field measuring device ( 20 ) with the line section ( 50 ) is positively connected and the magnetic field measuring device ( 20 ) at least one tenth of the length L of the two terminal contacts ( 30 . 40 ), and the magnetic field measuring device ( 20 ) a magnetic field sensor ( 60 . 65 ) and an evaluation circuit and an interface connection ( 80 ), wherein the interface port ( 80 ) has a supply voltage contact (VDD) and a reference potential contact (GND) and a signal terminal (OUT), and and the size of the magnetic field sensor ( 60 . 65 ) smaller than a quarter of the width B of the line section ( 50 ) and the magnetic field sensor ( 60 . 65 ) at least one fifth of the width B of one of the outer edges ( 90 ) of the line section ( 50 ), and the magnetic field measuring device ( 20 ), one of the size of a magnetic field sensor ( 60 . 65 ) acting magnetic field dependent output signal (VOUT) at the signal terminal (OUT) as a measure of the through the line section ( 50 ) to output flowing current. Ground strap ( 10 ) according to claim 1, characterized in that the magnetic field measuring device ( 20 ) two magnetic field sensors ( 60 . 65 ) with a different sensitivity ranges. Ground strap ( 10 ) according to claim 1 or claim 2, characterized in that the magnetic field measuring device ( 20 ) on the line section ( 50 ) is frictionally secured by means of an adhesive connection. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that the magnetic field sensor ( 60 . 65 ) and the evaluation circuit are monolithically integrated in a semiconductor body. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that the magnetic field measuring device ( 20 ) a flux concentrator ( 100 . 110 ) and the flux concentrator ( 100 , 110 ) has a plate-shaped, dovetail-shaped shape and has a small end face and a large end face, wherein the small end face immediately adjacent to the magnetic field sensor ( 60 ) is arranged. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that the small end face of the flux concentrator ( 100 . 110 ) substantially the size of the magnetic field sensor ( 60 ) corresponds. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that on both sides of the magnetic field sensor ( 60 ) a flux concentrator ( 100 . 110 ) is arranged. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that the magnetic field measuring device ( 20 ) comprises a Hall sensor designed as a Hall plate. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that the Hall plate perpendicular to the line section ( 50 ), wherein the main extension direction of the Hall plate parallel to the outer edges ( 90 ) of the line section ( 50 ) runs. Ground strap ( 10 ) according to one or more of the preceding claims, characterized in that a magnetic field sensor ( 60 . 65 ) comprises a threshold value switch. Method according to one or more of the preceding claims, characterized in that, when a threshold value is exceeded, the flow of current in the line section (FIG. 50 ) is interrupted. Method according to claim 11, characterized in that a magnetic field sensor ( 60 . 65 ) is designed as a switch and when a threshold value is exceeded, a signal for disconnecting one of the terminal contacts ( 30 . 40 ) is performed from the negative pole or from the ground point. Method according to one or more of the preceding claims, characterized in that the magnetic field measuring device ( 20 ) is calibrated. Method according to one or more of the preceding claims, characterized characterized in that the line section ( 50 ) comprises a ferromagnetic material.

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