DE102021101520A1 - Current sensor, cable and use of the current sensor - Google Patents

Abstract

Current sensor for measuring electrical currents, comprising a flux concentrator (1) and a sensor (2) which are connected to one another in a signal-conducting manner. The flux concentrator (1) consists of a soft magnetic and flexible material.

Description

technical field

The invention relates to a current sensor for measuring electrical currents, a cable and a use of the current sensor. The current sensor comprises a flux concentrator and a sensor which are connected to one another in a signal-conducting manner.

State of the art

Such a current sensor and its use are well known. A current sensor is used, for example, in a clamp meter. The current measuring clamp is used for non-contact measurement of electrical currents. Rigid iron cores serve as flux concentrators, which concentrate a magnetic field generated by the current. The magnetic field is used as a parameter for current measurement and is proportional to the current flow. The magnetic field is usually measured using a coil or a Hall sensor.
In contrast to a direct measurement of electrical currents, in which the circuit has to be broken in order to connect the ammeter to the electrical conductor, this is not necessary when measuring electrical currents using a clamp meter.
Due to the flux concentrators in the form of rigid iron cores, the measurement of electrical currents using ammeter clamps on arbitrarily shaped and/or flexible electrical conductors is not very satisfactory. Such arbitrarily shaped and/or flexible conductors then often have to be undesirably deformed, for example into a straight shape, in order to measure electrical currents.
The electrical conductors can be designed as cables.

Presentation of the invention

The invention is based on the object of further developing a current sensor of the type mentioned at the outset in such a way that the measurement of electric currents on arbitrarily shaped and/or flexible current-carrying electrical conductors, in particular cables, can be carried out simply and precisely without the arbitrarily shaped and/or having to deform the flexible conductor to measure the current. In addition, a use of such a current sensor is to be shown.

This object is achieved according to the invention with the features of claim 1, claim 11 and claim 12. The claims referring back to claim 1 refer to an advantageous embodiment of the current sensor.

In order to solve the task, it is provided that the flux concentrator consists of a soft-magnetic and flexible material. Due to the fact that the flux concentrator consists of a soft-magnetic and flexible material, it can be adapted to the geometry of arbitrarily shaped and/or flexible current-carrying conductors for measuring the current intensity. This considerably simplifies the measurement of the current strength, especially on such conductors. Due to the current sensor according to the invention, it is no longer necessary to deform non-straight, arbitrarily shaped conductors into a straight shape in order to be able to measure electrical currents with the ammeter clamp mentioned at the outset. In contrast to multi-part flux concentrators with a rigid iron core, only one flexible flux concentrator is sufficient to be able to easily and accurately measure electrical currents. In addition, the flexible flux concentrator can also be used in confined spaces. The space required for the current sensor is minimal.
The measurement of electrical currents in curved electrical conductors is possible without any problems, and the measurement accuracy is also very good because the measurement of electrical currents through the flexible flux concentrator takes place without contact and in the immediate vicinity of the electrical conductor. There are no undefined distances from the flux concentrator to the electrical conductor that would adversely affect the accuracy of the measurement. In addition, it is advantageous that the flexible flux concentrator is insensitive to possible vibrations of the electrical conductor during its intended use due to its flexibility.

The flux concentrator and the sensor can form a pre-assembled unit. This simplifies the handling of the current sensor, in particular its assembly on and its disassembly from the electrical conductor.

The flexible flux concentrator preferably consists of a flexible plastic. The flexible plastic can be formed by an HNBR material, for example.
Such a soft magnetic material has a high magnetic permeability. The greater the magnetic permeability, the better the magnetic field generated by the current is concentrated on the sensor.

The flux concentrator can be in the form of a clamp and can be clipped onto an electrical conductor for measuring electrical currents. Due to its clamp-like design, the flux concentrator can be clipped directly onto an electrical conductor.
The clip-on flexible flux concentrator has a Shape that corresponds to the shape of the arbitrarily shaped and / or flexible current-carrying conductor and encloses this preferably substantially completely. This results in a better concentration of the magnetic field on the sensor and an improved signal. Another advantage is that the current sensor according to the invention takes up less space when in use than the current measuring clamp mentioned at the outset.
The electrical conductor can have a round or rectangular cross-section.

The flux concentrator can be designed essentially in the form of a hollow cylinder and have a continuous longitudinal slot extending in the longitudinal direction at one circumferential point. The continuous longitudinal slot makes it possible to arrange the flux concentrator around any shaped and/or flexible electrical conductor even if the end faces of the electrical conductor are not freely accessible and the flux concentrator therefore cannot be mounted on the electrical conductor from one of the end faces .

By widening the longitudinal slot, the flux concentrator can be guided around an electrical conductor and clipped onto it. The widening preferably takes place elastically. A joint, such as with a current measuring clamp, is not required. The flexible material has a sufficiently high resilience.
The current sensor according to the invention has a very simple structure with few parts and can therefore be produced easily and inexpensively.

The sensor is preferably arranged in one of the opposite delimitations of the longitudinal slot in the circumferential direction. As a result, the sensor is visible to the user and can be easily and accurately positioned in relation to the electrical conductor.

The flux concentrator can be designed as a sheath for an electrical conductor. Electrical conductors, such as cables, are often insulated by a sheath. If a flux concentrator is used as a sheath, insulation of the electrical conductor is ensured on the one hand, and electrical currents through the conductor can be measured using the sheath on the other. The measurement of electrical currents is therefore particularly simple and inexpensive.

The sensor is preferably designed as a magnetic field sensor.
A magnetic field sensor for non-contact measurement of electrical currents is advantageous because the measured values are not falsified. The readings are particularly accurate.
Another advantage is that the sensor can form part of a cable. Only one such cable is required to measure electrical currents. There is no need for components that have to be produced separately and assembled/disassembled separately.

The invention also relates to a cable comprising a current sensor as described above, the current sensor forming an integral part of the cable.

This makes it particularly easy and accurate to measure currents in the cable. No separate component, such as a clamp meter, is required for the measurement.

The invention also relates to the use of a current sensor as described above.
The measurement of electric currents is particularly simple, especially when the installation space has only very compact dimensions, when the current sensor is used as an integral part of a cable sheathing of an electrically conductive cable that forms the electrical conductor. A larger additional installation space is not required just because of the current sensor.

To the same extent, the current sensor can be used as an integral part of a busbar/busbar sheathing of an electrically conductive busbar/busbar, which forms the electrical conductor.

In connection with e-mobility in particular, simple and inexpensive current measurement is becoming increasingly important. A current measurement has to be carried out more and more frequently on arbitrarily shaped and/or flexible current-carrying structures. The current sensor according to the invention with its flux concentrator made of soft magnetic and flexible material is particularly well suited for this. As a result, current measurements can preferably be carried out on an electric motor control of cars, e-bikes and household electrical appliances.

character list

Three embodiments of a current sensor according to the invention are based on the 1 until 5 explained in more detail.

• 1 einen erfindungsgemäßen Stromsensor, vor seiner Montage auf einen elektrischen Leiter,
• 2 den auf den elektrischen Leiter montierten Stromsensor aus 1,
• 3 einen Längsschnitt durch einen auf einen elektrischen Leiter montierten Stromsensor,
• 4 einen Querschnitt durch ein rundes Kabel mit einer in sich geschlossenen Ummantelung, die den Stromsensor umfasst,
• 5 einen Querschnitt durch ein rechteckiges Kabel bzw. Stromschiene/Busbar mit einer in sich geschlossen Ummantelung, die den Stromsensor umfasst.

the 1 until 5 show each in a schematic representation:

• 1 a current sensor according to the invention, before it is mounted on an electrical conductor,
• 2 the current sensor mounted on the electrical conductor 1 ,
• 3 a longitudinal section through a current sensor mounted on an electrical conductor,
• 4 a cross-section through a round cable with a self-contained sheath enclosing the current sensor,
• 5 a cross section through a rectangular cable or power rail / busbar with a self-contained sheath that includes the current sensor.

implementation of the invention

In the 1 and 2 each shows a cross section through an exemplary embodiment of the current sensor according to the invention, as well as a cross section through an electrical conductor whose electrical current is to be measured by the current sensor during its intended use.

In 1 the current sensor is shown before it is mounted on the electrical conductor 3 in its production-related state and in its already expanded state for mounting on the conductor 3 .
The current sensor includes the flux concentrator 1, which consists of a soft magnetic and flexible material, here an elastomer. The flux concentrator 1 is clamp-shaped. The clamp-like design results from the essentially hollow-cylindrical shape of the flux concentrator 1 , which has a continuous longitudinal slot 6 extending in the longitudinal direction 5 at a circumferential point 4 .
The flux concentrator 1 is in 1 shown in the elastically expanded state. By widening the longitudinal slot 6, it can be guided around the electrical conductor 3 and clipped onto it.

In 2 the current sensor clipped onto the electrical conductor 3 is shown. In addition to the flux concentrator 1, the sensor 2, a magnetic field sensor in the exemplary embodiment shown, is part of the current sensor. The sensor 2 is arranged in one of the opposite delimitations 8 , 9 of the longitudinal slot 6 in the circumferential direction 7 .

In 3 13 is a side view of the assembled current sensor 2 shown. It can be seen that the conductor 3 has any shape and/or is flexible.
The current sensor with its flux concentrator 1 and the sensor 2 is laid around this arbitrarily shaped and/or flexible current-carrying conductor 3 . The current sensor exactly reproduces the geometry of the electrical conductor 3 using the flexible material from which the flux concentrator 1 is made.

In the 4 and 5 an exemplary embodiment of a cable 10 with cable sheathing 11 or a busbar with sheathing is shown in each case.

The cable in 4 has a round, the cable in 5 on the other hand, a rectangular cross-section.

The electrical conductor in 4 is as a round cable, the conductor in 5 on the other hand designed as a conductor rail/busbar with a rectangular cross-section.

The cable sheathing 11 is closed in itself and comprises a current sensor with a flux concentrator 1 and a sensor 2, which are connected in a signal-conducting manner. The flux concentrator 1 consists of a soft magnetic and flexible material.

Claims (12)

Current sensor for measuring electrical currents, comprising a flux concentrator (1) and a sensor (2) which are connected to one another in a signal-conducting manner, characterized in that the flux concentrator (1) consists of a soft-magnetic and flexible material. current sensor after claim 1 , characterized in that the flow concentrator (1) and the sensor (2) form a preassembled unit. Ammeter according to one of the Claims 1 or 2 , characterized in that the flow concentrator (1) consists of a flexible plastic. current sensor after claim 3 , characterized in that the flexible plastic is formed by an HNBR material. Current sensor according to one of Claims 1 until 4 , characterized in that the flux concentrator (1) is clamp-shaped and can be clipped onto an electrical conductor (3) for measuring electrical currents. current sensor after claim 5 , characterized in that the flux concentrator (1) is essentially in the form of a hollow cylinder and has a continuous longitudinal slot (6) extending in the longitudinal direction (5) at a peripheral point (4). Current sensor according to one of Claims 5 or 6 , characterized in that the flux concentrator (1) can be guided around an electrical conductor (3) and clipped onto it by widening the longitudinal slot (6). Current sensor according to one of Claims 5 until 7 , characterized in that the sensor (2) is arranged in one of the opposite delimitations (8, 9) of the longitudinal slot (6) in the circumferential direction (7). Current sensor according to one of Claims 1 until 4 , characterized in that the flux concentrator (1) is designed as a sheath for an electrical conductor (3). Current sensor according to one of Claims 1 until 9 , characterized in that the sensor (2) is designed as a magnetic field sensor. Cable comprising a current sensor according to any one of Claims 1 until 10 , characterized in that the current sensor forms an integral part of the cable (10). Use of a current sensor according to one of Claims 1 until 10 as an integral part of a cable sheathing (11) of an electrically conductive cable (10) or a sheathing of an electrically conductive busbar.

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