WO2021083734A1 - Measurement system for electrical conductors, in particular hv conductors - Google Patents

Abstract

The invention relates to a measurement system for an electrical conductor, in particular HV conductor (11, 12), with shielding (18), preferably in a motor vehicle, in particular with electric drive, preferably purely electric drive, comprising at least one voltage tapping means (21) for tapping a voltage to be measured and comprising at least one current detection means (...) for inductively detecting a current to be measured, the voltage tapping means (18) and current detection means (...) being formed by a common assembly, in particular being housed in a common housing (16).

Description

Measurement system for electrical conductors, especially HV conductors

description

The invention relates to a measuring system for electrical conductors, in particular HV conductors, and a corresponding use, a corresponding motor vehicle, a corresponding set, a corresponding method for equipping at least one electrical conductor, a corresponding method for measuring current and / or voltage and a corresponding measuring arrangement,

Especially in the course of the development of electric drive systems (especially for electric vehicles, such as electric cars or electric trucks, but also in the development of trains or aircraft drives) as well as in the field of generating regenerative energy (especially for wind turbines and solar systems) an increasing need to carry out measurements of electrical quantities (such as voltage, current, power), especially in high-voltage areas of the corresponding systems.

It can happen that measurements have to be carried out in environments or on circuits that carry several 100 - 1000 volts DC or AC voltage.

This places special demands on the dielectric strength of measurement inputs on the one hand and electrical insulation between them on the other Measurement inputs (especially in the case of multi-channel measurement systems) and in particular to the (safety-relevant) insulation to an area of the measurement data recording that may be supplied with extra-low voltage and to any people in the vicinity.

At the same time, making electrical contact with electrical lines, in particular high-voltage lines on which voltages or currents are measured, is often comparatively complex. It is common, for example, to cut the lines, for example to carry out a current measurement on the line. This is often comparatively difficult in e-vehicles, for example, since corresponding electrical conductors can be comparatively thick and stiff or are often only accessible at a few (spatially limited) locations.

In any case, a (manipulated) line provided with a corresponding measuring system must be configured again in such a way that requirements for insulation and electrical safety are met, and functionality in terms of performance and, for example, shielding is ensured.

In the prior art, there are known ways of measuring a current in an electrical line. In particular, it is known to insert a shunt resistor into the line (this being separated for this purpose). As an alternative, it is known to carry out a current measurement by evaluating a magnetic field, which surrounds a current-carrying conductor, by means of an induction sensor. In this case, too, the line is disconnected so that the converter can be pushed over the line.

All in all, previous concepts have the disadvantage that a comparatively high set-up effort is required through the separation and installation of the conductor to be measured in the corresponding measuring system. In addition, the corresponding construction volumes are comparatively large. Especially when using a shunt resistor, the current measuring range is limited due to the self-heating of the shunt resistor (which increases quadratically with the current). It is the object of the invention to propose a measuring system for at least one electrical conductor, in particular HV conductor (with shielding), preferably in a motor vehicle, in particular with an electrical, preferably purely electrical, drive, with a reliable and safe measurement at comparatively should be made possible with little set-up effort. A further object of the invention is to propose a corresponding use, a corresponding motor vehicle, a corresponding set, a corresponding method for equipping at least one electrical conductor and a corresponding method for current and / or voltage measurement and a corresponding measuring arrangement.

The object is achieved in particular by the features of claim 1,

In particular, the object is achieved by a measuring system for at least one electrical conductor (or for measuring at least one electrical variable, in particular a voltage and / or a current of the electrical conductor), in particular for an HV conductor (high-voltage conductor) , preferably with shielding, more preferably in (or for a) motor vehicle, in particular with an electric, preferably purely electric, drive. In particular, the measuring system comprises at least one

Voltage tapping device for tapping a voltage to be measured and at least one current detection device for inductive detection of a current to be measured. The voltage tapping device and current detection device are particularly preferably formed by a common assembly, in particular integrated in a common housing, in particular accommodated (or arranged in a common housing).

A first idea of the invention is therefore to provide a measuring system that a

Current detection device for inductive detection of a current to be measured and a voltage tapping device for tapping off a voltage to be measured. The measuring system can be made particularly compact by means of a corresponding structural unit or assembly. A structural unit (assembly) is to be understood in particular as the voltage tapping device and current detection device being part of a common module that (together or in its entirety) is applied to at least one conductor (or the corresponding conductor is inserted there). In particular, the current detection device and voltage tapping device are spatially close to one another. A conductor section which is in contact with the voltage tapping device when the voltage is tapped can preferably overlap with a section which is inductively recorded by the current recording device or have a distance that is 20 cm, preferably 5 cm.

HV is an abbreviation for high voltage. Accordingly, a high-voltage conductor is designed for use in a high-voltage area. An HV range is to be understood as meaning, in particular, a range greater than or equal to 100 V, preferably greater than or equal to 500 V, more preferably greater than or equal to 1000 V.

A voltage tapping device is to be understood in particular as a device that is configured to be brought into (electrical) contact with the conductor to be measured, so that (when a corresponding evaluation device is connected) the voltage then tapped can be determined (and in particular output). The voltage tapping device does not have to (but can) already contain a configuration that contains a voltage determination (or voltage measurement) (i.e. is capable of determining a specific voltage value per se). The voltage value can, if necessary, be determined by an external component (for example an external control and / or evaluation unit).

A current detection device for inductive detection of a current to be measured is to be understood in particular as a device which can detect a magnetic field resulting from a flowing current. The current detection device does not (but can) contain a configuration which in turn determines a corresponding current from the detected magnetic field. A current determination (current calculation) can optionally also take place externally, in particular in an external control and / or evaluation unit.

According to a further (possibly independent, preferably further training)

Aspect of the invention, a measuring system (preferably of the above type) is proposed to solve the above-mentioned object, for at least an electrical conductor (or to measure it with respect to at least one electrical variable, such as in particular voltage and / or current), in particular HV conductor, preferably with shielding, more preferably in (or for a) motor vehicle, in particular with electrical, preferably purely electric drive, comprising a housing with an upper shell and a lower shell. At least one of the upper and lower shells, preferably both the upper and lower shells, have (each) at least one, preferably circular sector or circular segment, in particular semicircular cylindrical, receiving device, in particular receiving channel. The conductor to be measured can preferably be correspondingly received in the respective receiving device (in particular in the two receiving devices, in particular opposite one another).

Another idea of the invention is to provide a two-part (or possibly multi-part) housing that has at least one corresponding receiving device, in particular receiving channel, in order to receive the (respective) conductor to be measured (in particular to insert it there). As a result, it can be equipped with the measuring system in a simple manner. Overall, a comparatively safe and yet simple measurement is made possible.

In a preferred embodiment, the respective upper or lower shell is essentially plate-shaped (possibly apart from the receiving device and / or other recesses or receptacles).

The upper and lower shells can have a bottom wall and at least one side wall that extends along one edge of the bottom and protrudes therefrom.

The receiving device, in particular the receiving channel, preferably extends over a certain length, which is preferably at least 3 times, more preferably at least 8 times as large as a diameter (maximum extension perpendicular to the respective length direction) of the receiving device or receiving channel. The receiving device, in particular the receiving channel, preferably extends over at least 50%, more preferably at least 80%, possibly (at least approximately) 100% of its length always in the same direction or runs straight. A sector or circle segment, in particular semicircular-cylindrical receiving device is to be understood as a receiving device which is semicircular in cross section and otherwise forms a cylinder (in the general sense), in particular a straight cylinder.

In an assembled state of the measuring system (without a conductor arranged in it), an inner (open) volume (which is, for example, at least essentially formed by the receiving device (s)) can be less than or equal to 60%, possibly less than or equal to 40% of an outer volume (within an envelope surface). The measuring system is preferably comparatively compact. A (free) inner volume in this sense is to be understood as meaning, in particular, a volume that is accessible when the measuring system is open (in particular when the upper and lower shells are separated from one another).

Preferably, at least one reducing insert, which can be arranged or arranged in at least one of the two receiving devices, is provided to reduce a space in which the (respective) conductor to be measured can be received, in particular to reduce a space between the two (opposite) receiving devices.

In a particular embodiment, a (first) reducing insert is (in each case) provided, which is or can be arranged in a receiving device of the upper shell, and a corresponding (second) reducing insert, which is or can be arranged in the lower shell (opposite the first reducing insert). Specifically, the (respective) reducing insert can have an external geometry which is adapted (in particular corresponds) to the internal geometry of the corresponding receiving device. The (respective) reducing insert preferably has a partially ring-shaped, in particular a half-ring-cylindrical shape.

In particular, a reducing insert arranged in the corresponding receiving device forms a modified receiving device for receiving the corresponding conductor, which is reduced in size or narrowed compared to the corresponding receiving device without taking into account the reducing insert. The (respective) reducing insert can in particular define a (possibly narrowed or reduced) receiving channel. Particularly preferably, the (respective) reducing insert can be arranged reversibly, that is to say can be (completely) removed again from there after an arrangement in the corresponding receiving device. In this respect, the (respective) reducing insert is preferably exchangeable, so that an adaptation to different line diameters of electrical lines (HV lines) can take place in a simple manner. The (respective) reducing insert can preferably ensure a defined (central) position of the conductor to be measured, which improves the accuracy of the current measurement.

In embodiments, at least one receiving device and / or at least one reducing insert is made at least in sections, possibly completely, from a flexible material such as rubber or a rubber-like material. A flexible material is to be understood in particular as a material which has a modulus of elasticity of 10 GPa, preferably 1 GPa, more preferably 0.1 GPa (possibly greater than 0.0001 GPa or greater than 0.001 GPa). If the receiving device or the reducing insert are made of several materials, this should apply in particular to at least one (possibly several or all) material (s), in particular to a material or materials that contain at least 20 wt. %, preferably at least 50% by weight of the receiving device or the reducing insert. In the case of a flexible material, the line to be measured (HV line, in particular the outer sheath of the HV line) can particularly preferably be applied or inserted under pressure (for example by pressing the upper and lower shells) with a certain amount of strain relief. Furthermore, a tightness against the ingress of undesired substances (in particular water) is improved or even achieved in the first place. With a flexible design, a defined central position of the inner conductor is achieved in a particularly simple manner, which is important for (correct) inductive current measurement. Overall, a precise measurement is made possible in a simple manner.

The assembly (structural unit), in particular the housing, preferably the lower and / or upper shell (possibly in each case or, alternatively, only one of the upper and lower shell) can have at least one conductor shielding contacting device, preferably contacting clip Contacting a conductor shield (a conductor, in particular a high-voltage conductor with a shield line or shield). In particular, when the corresponding line (HV line) is inserted, exposed braided shield sections can be inserted (pressed) into the corresponding screen contacting device, preferably contacting clips. Such conductor shielding contacting devices (shielding contacting clips) can be used in a simple manner when inserting the conductor to be measured for a certain mechanical help against slipping out of the lines (HV lines) during assembly and / or serve as a centering aid towards the two ends of an outer jacket.

In embodiments, the tapping device can comprise at least one spring contact (compression spring contact), in particular a set of spring contacts (compression spring contacts), preferably as part of the upper and / or lower shell, in particular the lower shell, preferably a circuit board installed there. In this way, a contact for tapping (and ultimately measuring) the voltage can be carried out in a simple manner.

In embodiments, the measuring system has a carrier, in particular a circuit board. The carrier (the circuit board) can be part of the lower shell or be assigned to it. The carrier (the circuit board) can be built into the lower shell (detachably if necessary) or firmly connected to the lower shell (or, alternatively, the upper shell).

The carrier (in particular the circuit board) can (at least partially) have the tapping device, in particular at least one spring contact of the same (possibly all of the contacts or spring contacts of the same).

Alternatively or additionally, the carrier (the circuit board) can have at least one conductor shielding contacting device, preferably contacting clips (possibly all contacting clips), in particular two conductor shielding contacting devices, preferably contacting clips, for electrically connecting a severed conductor shielding section. Alternatively or additionally, the carrier (the circuit board) can at least partially be a sensor device, in particular a Hall sensor device

Current measuring device have.

Alternatively or additionally, the carrier (the circuit board) can have at least one control and / or communication device and / or a measurement signal processing device.

Alternatively or additionally, the carrier (the circuit board) can have at least one voltage supply device.

As an alternative or in addition, the carrier (the board) can have at least one recess (possibly an opening), in particular for the passage of a flux guiding bleaching leg.

The carrier is preferably constructed in one piece (if necessary, apart from devices attached there, such as the tapping device, monolithic) and can have a main body (which for example makes up more than 50% by weight of the entire carrier), which consists of at least one electrically insulating Material is made. A circuit board is to be understood in particular as a (thin) plate-shaped carrier. In embodiments, the circuit board can be rectangular. A thickness of the board is preferably a maximum of 0.1 times as large as a length and / or as a width and / or (especially in the case of non-rectangular geometries) as a maximum diameter (i.e. maximum distance of a point pair among all point pairs).

In any case, with such a common carrier (board) it can be achieved that various devices or components are kept in a specific (geometric) relationship to one another, which can simplify measurements. Furthermore, space-saving assembly is also made possible.

In embodiments, at least one flow concentrator, preferably a (in particular U-shaped) flow guide plate, is provided, which is preferably positioned (attached) in or on the upper shell. In preferred embodiments, at least one flux guide plate leg can be the carrier (in particular the board) and / or the lower shell (and / or the upper shell) penetrate. Such a flow concentrator simplifies a current measurement.

According to the embodiment, at least one connection device is provided for connecting a supply voltage and / or for transmitting signals. In particular, a voltage (or a corresponding value) tapped via the tapping device can be transmitted via such a connection device, so that this value can be further processed externally. Alternatively or additionally, a value of the measured magnetic field or flowing current can also be transmitted via such a connection device. In this respect, the connection device can be configured uni-directionally (that is to say enable transmission from the measuring system to the outside or vice versa) or bidirectional.

In preferred embodiments, at least two conductors to be measured (possibly at least three or at least four or at least five conductors to be measured) can (simultaneously) be recorded (or measured) in the system, in particular within the assembly (structural unit), preferably within the housing. or recorded. In a specific embodiment, exactly two conductors to be measured can be picked up or picked up (simultaneously).

A conductor is to be understood as an electrical conductor. A conductor can be structurally separate conductive elements from one another (for example two different electrical lines that are not directly connected to one another) or several (for example two) sections of an overall conductor.

The system (and / or its housing) preferably has a (flat) cuboid shape.

The system (and / or its housing) can have a height that is a maximum of 0.5 times, preferably a maximum of 0.2 times as large as a length and / or a maximum of 0.5 times, preferably a maximum of 0.2 times as large as a width and / or a maximum of 0.5 times, preferably a maximum of 0.2 times as large as a maximum diameter of the system or housing. Below a maximum diameter is to be understood as a distance between that pair of points (of the system or housing) that has the greatest distance from one another among all pairs of points.

The measuring system is preferably configured in such a way that a measurement (in particular current and / or voltage measurement) can be carried out on a conductor without severing it (completely). If necessary, however, it may be necessary to dismantle a shielding and / or insulation.

The above-mentioned object is also achieved in particular through the use of the above system for an electrical conductor, in particular HV conductor (possibly with shielding), in a motor vehicle, in particular with an electrical, preferably purely electrical, drive.

The above-mentioned object is in particular further achieved by a motor vehicle, in particular with an electric, preferably purely electric, drive, comprising the above system.

The above object is also achieved in particular by a set comprising a system of the above type containing at least two (different) reducing inserts which differ from one another with regard to their size and / or shape.

Preferably, at least two reducing inserts differ within the set by an inner diameter or a diameter of a receiving channel. The two reducing inserts can optionally have the same length and / or the same external geometry. The set particularly preferably comprises at least three or at least four or even at least five (different) reducing inserts.

The above-mentioned object is also achieved by a method for equipping at least one electrical conductor, in particular HV conductor (with shielding), preferably in a motor vehicle, in particular with an electrical, preferably purely electrical, drive, the electrical conductor in a system of the above Art is recorded. The HV conductor is preferably stripped with shielding in stages.

For this purpose, a special tool with adjustable back focal lengths and / or depths can, if necessary, be provided or used. The stepwise stripping is preferably carried out in such a way that an inner conductor and a screen (braided screen) are exposed, but are still separated from one another by an inner jacket.

Further procedural features emerge from the above description of the measuring system, in particular the corresponding functional features.

The above-mentioned object is also achieved in particular by a method for current and / or voltage measurement of an electrical conductor, in particular HV conductor (with shielding), preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive, the electrical conductor in a system of the above type is included and / or is equipped according to the method of the above type and wherein a voltage and / or current measurement is carried out. Further features of this method result from the above description of the method for equipping or measuring system (in particular with the corresponding functional features).

The above-mentioned object is also achieved in particular by a measuring arrangement comprising at least one electrical conductor, in particular HV conductor (with shielding), preferably in a motor vehicle, in particular with an electrical, preferably purely electrical, drive, and a measurement system of the above type.

Further embodiments emerge from the subclaims.

In the following, the invention is also described with regard to further features and advantages using an exemplary embodiment which is explained in more detail using the figures.

Show here;

1 shows an oblique view of a measuring system according to the invention; FIG. 2 components of the measuring system according to FIG. 1 as well as inserted conductors to be measured; FIG.

FIG. 3 shows an illustration according to FIG. 2 without an inserted conductor; FIG.

Fig. 4 Components of the measuring system according to Fig. 1 with inserted

Ladders;

FIG. 5 shows the components according to FIG. 4 in a different oblique view; FIG.

6 shows a circuit board according to the invention in an oblique view;

FIG. 7 shows the board according to FIG. 6 as well as reducing inserts; FIG.

FIG. 8 components of the measuring system according to FIG. 1; and

FIG. 9 Components of the measuring system according to FIG. 1. In the following description, the same reference numbers are used for identical and identically acting parts.

1 shows an oblique view of a measuring system according to the invention.

The measuring system comprises a connection device 10 via which (if necessary in the measuring system, for example, processed and / or standardized signals for example for voltages and / or currents) to a higher-level (or external) measuring and / or or recording unit can be provided or via which a connection line 29 is connected or can be connected.

Furthermore, HV conductors (or HV lines) 11, 12 are shown, which are inserted into the measuring system (HV adaptation). In the specific example according to FIG. 1, two HV lines are shown. However, it is also possible to configure the measuring system for three or more lines or just one line. The measuring system also has an upper shell 13 and a lower shell 14. The two HV conductors 11, 12 (in sections) are inserted between the upper shell 13 and lower shell 14. Specifically, the HV conductors themselves can be centered and held within the upper shell 13 and lower shell 14 by means of a set of reducing inserts (as described and illustrated in more detail below).

Furthermore, one recognizes in Fig. 1 the rear sides of two flux concentrators 15, which (which will also be described and illustrated in more detail below) are U-shaped and which preferably when the upper shell 13 is placed with their respective legs around the HV conductors 11, 12 (or one of these conductors) and thus contribute to the formation of a magnetic field that is generated by a current flowing through the respective HV conductor. This magnetic field can in turn be measured by Hall sensors or the like (for example within electronics) in order to determine a current through the respective conductor.

Upper shell 13 and lower shell 14 together form a housing 16. This housing 16 is (at least essentially) cuboid and preferably comparatively flat.

In FIG. 2, the measuring system according to FIG. 1 can be seen in an open state. The upper shell 13 was removed (based on FIG. 1). In particular, the inserted HV conductors 11, 12 can now be seen. These comprise an outer sheath 17, a shield (braided shield) 18, an inner sheath 19 and the actual conductor 20. 20 referred to as the HV conductor and the actual (internal) conductor as the "conductor" (i.e. without:

HV). As can be seen in FIG. 2, the HV conductors are stripped step by step so that the respective conductor 20 and the respective shielding (braided shield) 18 are exposed, but are still separated from one another by the respective inner sheath 19. This step-by-step stripping of the sheath can, if necessary, be carried out using a special tool with adjustable cutting widths and depths. The lower shell 14 shown in FIG. 2 contains at least one lower shell recess 30 through which a leg of a respective flow concentrator 15 can run.

Furthermore, a respective tapping device 21, preferably comprising several spring contacts 22, can be seen in FIG. 2 (or better still in FIG. 3). A voltage in the exposed section of the conductor 20 can be tapped (and thus measured) via this tapping device 21.

The (partially) stripped HV conductors 11, 12 are received in (respective) receiving devices 23.

By means of reducing inserts 24, reducing insert receiving grooves (guide grooves) are formed, which enable adaptation to the specific diameter of the HV conductors 11, 12 to be measured.

The reducing inserts 24 are interchangeable and can therefore be adapted to different line diameters of the HV conductors 11, 12. In each case two (opposite) reducing inserts 24 (one on the lower shell shown in FIGS. 2 and 3, one on the corresponding upper shell) form a hollow cylinder (circular in cross section).

It would also be conceivable to assign both the upper and lower shell to only one (respective) reducing insert, for example a one-piece (but longitudinally slotted) hollow cylinder. This would be particularly conceivable if the reducing insert is designed so flexibly that it can be easily stretched or spread apart (due to the slot then provided) so that the respective HV conductor can be inserted. If necessary, it would also be conceivable to dispense with reducing inserts, for example if the upper and lower shells already have the appropriate geometry.

Preferably, the reducing inserts comprise a flexible (rubber-like)

Material that presses against the outer sheath 17 of the HV conductors 11, 12, especially under pressure (when pressing the upper and lower shells) and, if necessary, provides strain relief and / or tightness against the ingress of water. Furthermore, the reducing inserts 24 can ensure a defined central position of the conductor 20, which is advantageous for a correct (inductive) current measurement.

When the HV conductors 11, 12 are inserted, exposed sections of the shielding (of the braided shield) 18 can be inserted, in particular pressed, into corresponding conductor shielding contacting devices 25 (here in the form of corresponding contacting clips or shielding contacting clips).

These conductor shielding contacting devices 25 can be arranged (soldered) on a printed circuit board 26 (see, for example, FIG. 4 or 6), possibly built into / on the lower shell 14, and thus in particular enable continuous contact of the separated shield 18.

Furthermore, when inserting the HV conductors 11, 12, the conductor shielding contacting devices 25 can provide a (certain) mechanical help against slipping out of the HV conductors 11, 12 (during assembly) and, if necessary, as a centering aid against (exposed) ends 27 of the Outer jacket 17 are used.

The (respective) HV conductor 11, 12 inserted into the (respective) receiving device 23 or the corresponding reducing insert receiving groove of the reducing inserts 24 can now (simultaneously) with the exposed (inner) conductor 20 onto the spring contacts 22 (or a corresponding one Contact spring). These spring contacts can also be arranged (soldered) on the circuit board 26 and thus enable contact for the voltage measurement.

In addition to tapping the voltage on the conductors 20 of the HV conductors 11, 12, the measuring system can also be used to measure currents through the conductors 20.

According to the embodiment, such a current measurement is carried out inductively by measuring a magnetic field which surrounds the current-carrying conductors 20. This is further illustrated in FIGS. 4 and 5. According to FIGS. 4 and 5, the HV conductors 11, 12 or their (inner) conductors 20 are each surrounded by U-shaped flux concentrators 15 (in the form of flux guide plates), in particular made of highly permeable material.

The flux concentrators 15 form a magnetic field around the conductors 20 in such a way that Hall sensors 28 of a (respective) current detection device 33, which measure these fields (or their field strength), have a (preferably) homogeneous magnetic field flowing through them.

By positioning the flux concentrators (flux guide plates) 15 in the upper shell 13, they can be removed together with the latter and then put back on again (which, however, is not mandatory).

For this purpose, the circuit board 26 and the lower shell 14 can have corresponding cutouts (openings) through which the legs of the flux concentrators 15 (the flux guide plates) can extend.

By adjusting the HV conductors 11, 12 in the lower shell 14 by means of the reducers 24 and in particular through their fixed mechanical relationship to the lower shell 14 or upper shell 13, it is made possible or simplified that a central axis of the HV conductors 11, 12 (always ) comes to rest in the same position within the flux concentrators (flux guide plates) 15. As a result, an influence of a position of the (respective) Hall sensor 28 in relation to a conductor axis in relation to the current measurement is eliminated or at least reduced.

The circuit board 26 can be used in addition to the conductor shielding contacting devices

25 for the shielding (the braided shield) 18 and / or the tapping device or its spring contacts 22 for tapping (measuring) the voltage on the conductor 20 and / or the Hall sensors 28 one or more of the following (electronic) structures (functional groups) exhibit:

- a sensor signal processing for an HV voltage measurement (at least comprising a division device, a filter and / or analog-digital converter or ADC); - a sensor signal processing for an inductive current measurement, in particular by Hall sensors (at least comprising an amplifier, a filter and an ADC);

- a galvanic isolation between a signal conditioning of the HV voltage measurement and a (digital) evaluation and / or communication electronics and a communication and voltage supply interface;

- A (digital) evaluation and communication electronics, comprising at least one microcontroller and / or (digital) signal processor, if necessary for filtering, comparing and / or linearizing measurement signals and / or for providing a communication protocol for a higher-level measurement or Recording unit;

- A voltage supply circuit which, if necessary, electrically isolated, supplies energy to an HV side (high-voltage side) and supplies (electronic) circuits located there;

an adapter circuit for adapting communication signals from the possibly provided microcontroller or (digital) signal processor to a selected physical communication interface (for example CAN, Ethernet and / or POF or a polymeric optical fiber).

In Fig. 6, the board can be seen again in isolation. In particular, recesses 31 are formed there (partly as a breakthrough) in order to be able to pass through the legs of the flow concentrators 15.

In Fig. 7, the board 26 including two reducing inserts 24 can be seen. It can also be seen there that the reducing inserts 24 have recesses 32 in order to be able to pass through the conductor shielding contacting devices 25.

In FIG. 8, the upper shell 13 including the flow concentrators 15 can be seen. In FIG. 9, the circuit board 26 with the Hall sensors 28 can again be seen in the installed state. A corresponding cover or base of the lower shell 13 can also be arranged above the plate 26.

The measuring system according to the invention is particularly preferably used on HV lines in a drive train of electric vehicles,

Advantages of the measuring system according to the invention are, in particular, little or no destruction of the HV conductors to be measured, comparatively little effort in preparing the HV conductors for contacting, a comparatively small volume, the possibility of simultaneous contacting of two or more HV conductors within a measuring system, a comparatively low effort for laying / contacting the HV conductors inside the measuring system, no additional self-heating due to a current measurement, since there is no need for a shunt resistor, and comparatively less Expenditure for mounting and securing the measuring system as well as improving (ensuring) a seal.

In the description of the figures, a measuring system for two HV conductors is shown. However, the number “two” is not mandatory, so that all the features in the description of the figures also apply to a different number, for example for one conductor or more than two conductors.

In addition, it should be pointed out that all of the parts described above, seen on their own and in any combination, in particular the details shown in the drawings, are claimed as embodiments of the invention. Changes to this are possible.

Reference number

10 Connection device

11 HV conductor (HV conductor)

12 HV conductors (HV conductors)

13 upper shell

14 lower shell

15 flow concentrator 16 housing

17 outer jacket

18 shielding (braided shield)

19 inner jacket

20 (inner) conductors

21 Pickup device

22 spring contact

23 Reception facility

24 Reduction insert

25 Conductor shield contacting device

26 circuit board

27 end

28 Hall sensor

29 Connection cable

30 Lower shell recess

31 recess

32 recess

33 Current measuring device

Claims

Expectations

1. Measurement system for at least one electrical conductor, in particular HV conductor (11, 12) with shielding (18), preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive, comprising at least one voltage tapping device (21) for tapping a voltage to be measured and at least one current detection device (33) for inductive detection of a current to be measured, the voltage tapping device (18) and current detection device (33) being formed by a common assembly, in particular being accommodated in a common housing (16).

2. Measuring system, in particular according to claim 1, for at least one electrical conductor, in particular HV conductor (11, 12) with shielding (18), preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive comprising a housing (16) with an upper shell (13) and a lower shell (14), both the upper (13) and the lower shell (14) each having at least one, preferably semicircular-cylindrical, receiving device (23), in particular receiving channel, of this type that the conductor to be measured can be received in the two receiving devices (23).

3. System according to claim 1 or 2, characterized by at least one, in particular in at least one of the two corresponding receiving devices (23) arrangable or arranged, reducing insert (24) for reducing a space in which the conductor to be measured can be received, in particular for reducing a space between the two receiving devices (23),

4. System according to one of the preceding claims, characterized in that at least one receiving device (23) and / or at least one reducing insert (24) is made at least in sections, possibly completely, from a flexible material.

5. System according to one of the preceding claims, characterized in that the assembly, in particular the housing (16), preferably the lower (14) and / or upper shell (13), at least one conductor shielding contacting device (25), preferably contacting clip, for contacting a shield (18).

6. System according to one of the preceding claims, characterized in that the tapping device (21) has at least one spring contact (22), in particular a set of spring contacts, preferably as part of the upper (13) and / or lower shell (14) and / or a carrier, in particular a circuit board (26).

7. System according to one of the preceding claims, characterized by a carrier, in particular a circuit board (26), preferably receiving: at least partially at least one tapping device (21), in particular at least one spring contact (22) thereof, and / or at least partially at least one conductor shielding contacting device (25), preferably contacting clip, in particular at least two conductor shielding contacting devices, preferably contacting clips, for electrically connecting a separated conductor shielding section, and / or at least partially a sensor device (28), in particular Hall sensor device, of the current detection device, and / or a control and / or communication device and / or a measurement signal processing device and / or a voltage supply device and / or at least one recess (31), in particular for passing through a flux guide plate leg.

8. System according to one of the preceding claims, characterized by at least one flow concentrator (15), preferably one, in particular U-shaped, flux guide plate, which is preferably positioned in or on the upper shell (13), preferably at least one flux guide plate leg penetrates the carrier, in particular the plate (26), and / or the lower shell (14).

9. System according to one of the preceding claims, characterized by at least one connection device (10) for connecting a supply voltage and / or for transmitting signals.

10. System according to one of the preceding claims, characterized in that in the system, in particular within the assembly, preferably within the housing (16), at least two conductors to be measured can be received and / or measured.

11. System according to one of the preceding claims, characterized in that the system and / or its housing (16) has a, preferably flat, cuboid shape and / or a height that is a maximum of 0.5 times, preferably a maximum of 0.2 - times as large as a length and / or a maximum of 0.5 times, preferably a maximum of 0.2 times as large as a width and / or a maximum of 0.5 times, preferably a maximum of 0.2 times as large is like a maximum diameter.

12. System according to one of the preceding claims, characterized in that the system is configured to carry out a measurement, in particular a current and / or voltage measurement, on a conductor without severing it.

13. Use of a system according to one of the preceding claims for at least one electrical conductor, in particular HV conductor (11, 12) with shielding, in a motor vehicle, in particular with an electrical, preferably purely electrical drive.

14. Motor vehicle, in particular with an electric, preferably purely electric drive, comprising a system according to one of claims 1 to 12.

15. Set comprising a system according to one of claims 1 to 12, containing at least two reducing inserts (24) which differ from one another in terms of their size and / or shape.

16. A method for equipping at least one electrical conductor, in particular HV conductor (11, 12) with shielding, preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive, the electrical conductor in a system according to one of claims 1 to 12 is recorded.

17. The method according to claim 16, characterized in that the conductor designed as a high-voltage conductor with shielding is stripped in stages.

18. A method for current and / or voltage measurement of at least one electrical conductor, in particular HV conductor (11, 12) with shielding, preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive, the electrical conductor in a system according to one of claims 1 to 12 is included and / or is equipped according to the method according to claim 16 or 17 and wherein a voltage and / or current measurement is carried out,

19. Measuring arrangement, comprising at least one electrical conductor, in particular HV conductor (11, 12) with shielding, preferably in a motor vehicle, in particular with electrical, preferably purely electrical, drive, as well as a system according to one of claims 1 to 12,