DE20320473U1 - Electrical resistor assembly used to measure current from battery or generator for road vehicle electrical network has separate flat contact tags - Google Patents

Abstract

The electrical resistor assembly (1) has two separate 100 micro-Ohm resistors (2,3) carrying current from the road vehicle battery or generator. It has a large flat contact tag (6) with a hole (13) connected between the resistors. Smaller tags (9,10) are connected to the outer ends of the resistors and have holes (11,12). The tags are welded (4,5,7,8) to the resistors. Measurement terminals (14,15,16) are connected to each of the contact tags. A small rectangular aperture (17) in the large tag may be used for calibration and influences division of current in the tag.

Description

The invention relates to a resistor arrangement, in particular for current measurement in a vehicle electrical system, according to the preamble of claim 1 and a measuring circuit with such a resistor arrangement according to claim 13th

Out EP 0 605 800 B1 . EP 1 030 185 A2 and EP 0 716 427 B1 Low-resistance resistor arrangements are known which can be used for measuring high currents. These known resistor assemblies consist of two separate, at least partially plate-shaped connection elements for current feed-in or current dissipation and a plate-shaped resistance element arranged between the two connection elements and electrically and mechanically connected to them, the connection of the resistance element to the adjacent connection elements being carried out by welding. Furthermore, the known resistor arrangement has two separate measuring connections in order to measure the electrical voltage dropping across the resistance element in accordance with the known four-wire technology, from which the electrical current flowing through the resistance element can be calculated according to Ohm's law.

A disadvantage of this known resistor arrangement However, the fact is that to measure multiple currents one correspondingly large number of resistor arrangements is required.

The object of the invention is therefore based on the effort of measuring several different electrical streams to reduce.

This task is based on the known resistor arrangement described above according to the preamble of claim 1, by the characterizing features of the claim 1 and solved by a measuring circuit according to claim 13.

The invention encompasses the general technical teaching, the known resistor arrangement described above to improve that several different electrical streams can be measured by providing several separate resistance elements, which can each carry an electrical current.

In the preferred embodiments of the Invention has the inventive resistance order two separate resistance elements, so that at the same time two electrical currents can be measured.

However, it is within the scope of the invention also possible, that the resistor arrangement is more than two (e.g. four) apart has separate resistance elements by a correspondingly larger number electrical currents to be able to measure.

The individual resistance elements can also a different width and / or thickness with respect to the direction of current flow to meet the current load.

The individual resistance elements are preferably independent here connected in a star shape by the number of resistance elements and are electrically contacted by a common connection element, while the further electrical contacting of the individual resistance elements by means of a separate connection element in each case.

The actual measurement of the over the individual resistance elements dropping electrical voltage is preferably carried out according to the known four-wire technology through measuring connections that electrically and mechanically connected to the individual connection elements are.

The individual measurement connections are preferably here each arranged directly at the limits of the resistance elements, so that the voltage measurement is not due to the inside of the connection elements falling electrical voltage is falsified.

In addition, the measurement connections limit within the connection elements of the resistor arrangement according to the invention preferably directly to the side edges of the connection elements, which is also is technically advantageous.

In a preferred embodiment of the Invention is additional a circuit board with a measuring circuit is provided, the circuit board with its main plane parallel to the main surfaces of the plate-shaped resistance elements arranged and mechanically and / or electrically connected to them is. The resistor arrangement according to the invention thus forms a structural with the circuit board with the measuring circuit Unit, being the influence of electromagnetic interference and thermal voltages due to a small distance between the resistor arrangement and the board is minimized.

The mechanical connection of the board with the resistor arrangement, for example, through the measuring connections, by soldering the circuit board to the resistor assembly is connected.

However, it is alternatively also possible that the Circuit board through a spacer mechanically with the resistor assembly is connected, the spacer balancing mechanical-thermal Allows stretching.

It is also in the common Connection element of the individual resistance elements preferably a breakthrough arranged the current distribution in the common To influence the connection element in a targeted manner.

The breakthrough can be, for example act as a rectangular recess, the opening being preferred directly to the measurement connection in the common connection element borders.

With a fork-shaped design of the resistor arrangement according to the invention the breakthrough to influence the current distribution is preferred arranged in the middle between the two resistance elements.

The mechanical connection between the connection elements and the resistance elements are preferably made through a weld, however is the invention with regard to the connection between the connection elements and the resistance elements with other cohesive joining processes realizable, such as by brazing.

It should also be mentioned that the connection elements for current supply or current dissipation preferably consist of copper or a similarly conductive copper connection, while the low-resistance elements preferably consist of a CuMnNi connection (eg Manganin ^® ).

Are suitable for low-resistance current measurement preferably resistors, which are in the range between 1μΩ and 1mΩ. However, the invention is in terms of resistance Resistance elements not on the above-mentioned value range limited.

Finally, the invention encompasses also a measuring circuit with at least one resistor arrangement according to the invention, this measuring circuit is particularly suitable for current measurement in one Motor vehicle electrical system is suitable.

The resistor arrangement according to the invention can either ground side ("low side ") or voltage side ("high side") switched, however is it also possible a resistor arrangement each on the ground side and on the voltage side provided.

When using the resistor arrangement according to the invention A resistance element can be used to measure current in a motor vehicle electrical system for example, be arranged in a battery circuit while a another resistance element arranged for example in a generator circuit can be. In this way, both the battery power as well the generator current can be measured directly, while the vehicle current from the both measured values can be derived.

However, it is alternatively also possible for a Resistance element in the battery circuit of the motor vehicle electrical system is arranged while the other resistance element measures the vehicle current and with the is connected to individual consumers. In this case, the resistance arrangement according to the invention a direct measurement of the battery current and the vehicle current, while the generator current can be derived from these two measured values can.

In any case, the invention enables simple Way a reliable Measured value acquisition for Combined electronic battery and power management, which for Ensuring the power supply in vehicle electrical systems, in particular of motor vehicles with constantly increasing number of electrical consumers is becoming increasingly important.

Instead of the way described made of electron beam welded The resistor arrangement can also be made of composite material in other ways getting produced. For example, two from the Resistance alloy or strips made of copper in to connect in a known manner by roll plating and by the resistance elements Partial removal, in particular milling, of the copper layer. The shaping and the separation of the desired resistor arrangements can also here, for example, by punching.

Other advantageous developments the invention are characterized in the dependent claims or are Below, along with the description of the preferred embodiments of FIG Invention with reference to the figures explained. Show it:

1 a supervision of a resistor arrangement according to the invention,

2 2 shows a plan view of an alternative exemplary embodiment of a resistor arrangement according to the invention,

3 a side view of the resistor assembly 1 with a circuit board with a measuring circuit,

4 a supervision of several arrangements according to the invention in the prefabricated state during manufacture,

5 a measuring circuit according to the invention with two resistor arrangements according to the invention,

6 an alternative embodiment of a measuring circuit according to the invention,

7a to 7d simplified exemplary embodiments of measuring circuits according to the invention and

8th a further embodiment of a resistor arrangement according to the invention with four resistor elements.

The supervisory representation in 1 shows a resistor arrangement according to the invention 1 , which can be used, for example, in a motor vehicle electrical system to measure the generator current and the battery current, as will be described in detail later.

For this purpose, the resistor arrangement 1 two spatially separated resistance elements 2 . 3 which each consist of a copper alloy (eg Manganin ^® ) and have a resistance of eg 100 μΩ.

The two resistance elements 2 . 3 are each by a weld seam 4 . 5 with a common connection element 6 connected, which consists of copper and is used to feed or dissipate electricity.

Furthermore, the two resistance elements 2 . 3 one additional weld seam each 7 . 8th each with a separate connection element 9 respectively. 10 connected, the two connection elements 9 . 10 enable separate power supply or power dissipation.

For contacting the connection elements 6 . 9 . 10 each have a power connection hole 11 . 12 respectively. 13 on.

The actual current measurement is carried out in accordance with the four-wire technology known per se through measuring connections 14 . 15 . 16 , each with one of the connection elements 6 . 9 respectively. 10 are connected. By measuring the electrical voltage between the two measuring connections 14 and 16 can, for example, by the resistance element 2 Flowing electrical current can be determined while the electrical voltage between the measuring connections 15 and 16 the electrical current through the resistance element 3 reproduces.

The measurement connections 14 . 15 . 16 are in each case directly to the resistance elements 2 . 3 arranged adjacent to measurement errors due to the inside of the connection elements 6 . 9 . 10 to prevent falling electrical voltage.

In addition, the measurement connections 14 . 15 . 16 as shown directly on the side edges of the connection elements 6 . 9 . 10 arranged, which is also advantageous metrologically.

Furthermore, the resistor arrangement 1 in the connection element 6 a breakthrough 17 on that directly to the measurement connection 16 adjoins and the current distribution in the connection element 6 specifically influenced.

This in 2 shown alternative embodiment of a resistor arrangement according to the invention 1' largely agrees with that described above and in 1 illustrated embodiment of the resistor arrangement 1 agree, so that in the following to avoid repetition largely refer to the above description 1 is referenced and the same reference numerals are used for corresponding parts, which are only identified by an apostrophe.

A special feature of this embodiment is that the common connection element 6 ' two separate contact tongues 18 ' . 19 ' for power dissipation.

From the side view in 3 it can also be seen that the in 1 resistance arrangement shown 1 with a circuit board 20 is connected, the board 20 carries a measuring circuit in SMD design. To simplify this, only two SMD components are exemplary 21 . 22 of the measuring circuit.

The mechanical and electrical connection of the board 20 with the resistor arrangement 1 takes place through the measuring connections 14 . 15 and 16 , the small distance between the board 20 and the resistor arrangement 1 ensures that the influence of electromagnetic interference and thermal voltages remains low.

4 finally shows a top view of several resistor arrangements 23 - 26 the in 1 shown type in the prefabricated state.

In the manufacture of the resistor assemblies 23 - 26 will initially be three elongated ribbons 27 . 28 . 29 along their long edges by welds 30 . 31 connected together, with the two outer bands 27 . 29 are made of copper, while the middle band 28 consists of the copper alloy mentioned and later the resistance elements 2 . 3 of the individual resistor arrangements 23 - 26 forms.

After welding the tapes together 27 - 29 are in the still related resistance arrangements 23 - 26 transverse recesses 32 - 35 punched out from the side edge of the tape 27 starting inwards to the weld 31 extend so that the recesses 32-35 in the resistor arrangements 23 - 26 the connection elements 9 and 10 as well as the resistor arrangements 2 and 3 separate from each other.

In addition, in the individual resistor arrangements 23 - 26 recesses 11.1 - 11.4 . 12.1 - 12.4 and 13.1 - 13.4 punched out, which are used to connect separate cables.

Breakthroughs are still in progress 17.1 - 17.4 in the individual resistor arrangements 23 - 26 punched out, the breakthroughs 17.1 - 17.4 serve to influence the current distribution in the resistor arrangements.

Finally, the individual resistor arrangements are then along predetermined dividing lines 36 separated, to then the in 3 shown circuit board 20 to be able to mount with the measuring circuit.

5 finally shows a measuring circuit using two resistor arrangements according to the invention 37 . 38 is used for current measurement in a motor vehicle electrical system.

The resistor arrangement 37 is arranged here on the ground side ("low side"), with a resistance element of the resistance arrangement 37 in the circuit of a battery 39 is arranged, while the other resistance element of the resistance arrangement 37 in the circuit of a generator 40 is arranged. The resistor arrangement 37 thus enables both a battery current i _B and a generator current i _G to be measured, with a vehicle current i _C resulting as a negative sum of the two partial currents i _B and i _G.

The other resistor arrangement 38 also enables a measurement of the partial currents i _B and i _G , as an element of the resistance order 38 in the circuit of the battery 39 is arranged, while the other resistance element of the resistance arrangement 38 in the circuit of the genera tors 40 is arranged.

The on the two resistor arrangements 37 . 88 Tapped currents are (only shown here in simplified form) a monitoring unit 41 (EPM - Electronic Power Management), which, depending on the measured values, a fuse box 42 , multiple consumers 43 . 44 as well as an electronic control unit 45 (ECU - Electronic Control Unit) controls a motor vehicle.

There is also a starter 46 shown with the summation point of the resistor arrangement 38 connected is.

The resistor arrangements according to the invention 37 . 38 advantageously enable the measurement of the battery current i _B and the generator current i _G , the vehicle current i _{C being able to be} derived therefrom.

The circuit diagram in 6 shows an alternative embodiment of a measuring circuit according to the invention, in which also a resistor arrangement according to the invention for current measurement 47 with two resistance elements 48 . 49 is used.

The resistance element 49 is in a circuit branch with a generator 50 arranged and therefore allows measurement of a generator current i _G.

The other resistance element 48 on the other hand is in a circuit branch together with a battery 51 arranged and thus enables the measurement of a battery current i _B.

In this embodiment, the resistor arrangement according to the invention 47 in terms of the generator 50 and the battery 51 arranged on the voltage side ("high side").

On the common connection element of the resistor arrangement according to the invention 47 are a starter 52 and several electrical consumers connected, the consumers are not shown for simplicity.

The actual current measurement is carried out by an integrated circuit 53 (ASIC - Application Specific Integrated Circuit), for example in DE 102 37 126.1 is described in detail. The content of this document is therefore the present description with regard to the structure and operation of the integrated circuit 53 fully attributable to a detailed description of the integrated circuit 53 can be dispensed with.

However, it should be mentioned that the integrated circuit 53 has a measurement input VBAT, to which a voltage divider is connected, which consists of two resistors 54 . 55 there is resistance 54 is connected to ground while the resistor 55 is connected on the voltage side to the vehicle electrical system voltage.

Furthermore, the integrated circuit 53 a voltage-side voltage tap RSHL on the common connection element of the resistor arrangement 47 connected.

The other two connection elements of the resistor arrangement 47 are separated with an additional measuring input ETS or RSHH of the integrated circuit 53 connected.

Finally they show 7a to 7d simple exemplary embodiments of alternative modifications of measuring circuits according to the invention, the measuring circuit in FIG 7a is described.

Here, too, is a resistor arrangement according to the invention 56 with two resistance elements 57 . 58 used, the resistance element 57 together with a battery 59 is arranged in a circuit branch.

The resistance element 58 the resistor arrangement 56 is, however, arranged in another circuit branch, via which all consumers of the vehicle electrical system are supplied with electricity.

To the common connection element of the resistor arrangement 56 are a starter here 60 and a generator 61 connected.

In this embodiment, the resistor arrangement 56 also arranged on the voltage side.

This in 7b The illustrated embodiment of a measuring circuit according to the invention also has a resistance arrangement according to the invention 62 with two resistance elements 63 . 64 on, with the resistance element 64 again together with a battery 65 is arranged in a circuit branch.

The other resistance element 63 on the other hand is in a circuit branch together with a generator 66 arranged.

In this embodiment, the Battery current and generator current can be measured directly during the Vehicle current is derived from these two measurements.

At the common connection of the resistor arrangement according to the invention 62 is a starter here 67 and a tap for supplying the vehicle electrical system is connected.

The embodiments in the 7c and 7d are similar to the exemplary embodiments in FIGS 7a and 7b , so that in the following to avoid repetition reference is made to the above description and the same reference numerals are used for matching components, which are identified only for distinction by an apostrophe.

A peculiarity of the embodiment according to 7c consists in that to the common connection element of the resistor arrangement 56 ' a circuit branch is connected in which the battery 59 ' located.

One of the two separate connection elements of the resistor arrangement 56 ' is, however, connected to a circuit branch in which a Parallel connection from the starter 60 ' and the generator 61 ' is arranged.

The other connection element of the two separate connection elements of the resistor arrangement 56 ' is, however, connected to a circuit branch in which the vehicle current flows.

In the embodiment according to 7d is to the common connection element of the resistor arrangement 62 ' also a circuit branch is connected in which the battery 65 ' located.

The two separate connection elements of the resistor arrangement 62 ' are connected to two circuit branches, in which the starter 67 ' or the generator 66 ' is arranged.

Finally shows 8th an embodiment of a resistor arrangement 68 , which largely with the in 1 illustrated embodiment coincides, so that reference is made below to avoid repetition of the above description.

A special feature of the resistor arrangement 68 consists of a total of four connection elements 69.1 - 69.4 and accordingly also four resistance elements 70.1 - 70.4 are provided.

In each of the four connection elements 69.1 - 69.4 is again a power connection hole 71.1 - 71.4 arranged.

Finally, is also on each of the connection elements 69.1 - 69.4 one measuring connection each 72.1 - 72.4 appropriate.

The invention is not based on the above described preferred embodiments limited. Rather, a variety of variations and modifications are possible also make use of the inventive idea and therefore in fall within the protection zone.

Claims (23)

Resistor arrangement ( 1 . 1' . 37 . 38 ), especially for measuring battery and generator current in a vehicle electrical system, with two separate plate-shaped connection elements ( 6 . 6 ' . 9 . 9 ' ) and one between the two connection elements ( 6 . 6 ' . 9 . 9 ' ) arranged and connected to them electrically and mechanically plate-shaped first resistance element ( 2 . 2 ' ), characterized by at least one of the first resistance element ( 2 . 2 ' ) separate, plate-shaped further resistance element ( 3 . 3 ' ) between one of the two connection elements ( 6 . 6 ' . 9 . 9 ' ) of the first resistance element ( 2 . 2 ' ) and another connection element ( 10 . 10 ' ) arranged and with these connection elements ( 6 . 6 ' . 10 . 10 ' ) is electrically and mechanically connected. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to claim 1, characterized in that for detecting the over the resistance elements ( 2 . 2 ' . 3 . 3 ' ) falling electrical voltage measuring connections ( 14 - 16 . 14 ' - 16 ' ) are provided, which are electrically and mechanically connected to the individual connection elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) are connected. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to claim 2, characterized in that the measuring connections ( 14 - 16 . 14 ' - 16 ' ) directly to the resistance elements ( 2 . 2 ' . 3 . 3 ' ) and / or on the side edges of the connection elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) are arranged adjacent. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to one of the preceding claims, characterized by a circuit board ( 20 ) with a measuring circuit, whereby the board ( 20 ) parallel to the plate-shaped resistance elements ( 2 . 2 ' . 3 . 3 ' ) arranged and electrically connected to them. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to claim 4, characterized in that the circuit board ( 20 ) with the measuring circuit through the measuring connections ( 14 - 16 . 14 ' - 16 ' ) mechanically with the connection elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) connected is. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to claim 4, characterized in that the circuit board ( 20 ) with the measuring circuit by a spacer mechanically with the connection elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) and / or the resistance elements ( 2 . 2 ' . 3 . 3 ' ) connected is. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to one of the preceding claims, characterized in that in the common connection element ( 6 . 6 ' ) of the resistance elements ( 2 . 2 ' . 3 . 3 ' ) a breakthrough ( 17 . 17 ' . 17.1 - 17.4 ) is arranged to influence the current distribution. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to claim 7, characterized in that the opening ( 17 . 17 ' . 17.1 - 17.4 ) in the middle between the two resistance elements ( 2 . 2 ' . 3 . 3 ' ) is arranged. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to one of the preceding claims, characterized in that the connecting elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) with the resistance elements ( 2 . 2 ' . 3 . 3 ' ) are welded. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to one of the preceding claims, characterized in that the connecting elements ( 6 . 6 ' . 9 . 9 ' . 10 . 10 ' ) consists of copper or a copper compound. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to any one of the preceding claims, characterized ge indicates that the resistance elements ( 2 . 2 ' . 3 . 3 ' ) consist of Manganin®. Resistor arrangement ( 1 . 1' . 37 . 38 ) according to one of the preceding claims, characterized in that the common connection element ( 6 ' ) of the two resistance elements ( 2 ' . 3 ' ) two current contacts for power dissipation ( 18 ' . 19 ' ) having. Measuring circuit, in particular for measuring battery current and generator current in a vehicle electrical system, with a first resistance element ( 48 . 57 . 64 ), which is arranged in a first circuit branch, a first voltage tap for measuring the voltage across the first resistance element ( 48 . 57 . 64 ) falling electrical voltage, a second resistance element ( 49 . 58 . 63 ), which is arranged in a second circuit branch, and with a second voltage tap for measuring the over the second resistance element ( 49 . 58 . 63 ) falling electrical voltage, characterized in that the two resistance elements ( 48 . 49 . 57 . 58 . 63 . 64 ) together in a resistor arrangement ( 47 . 56 . 62 ) are arranged and mechanically connected. Measuring circuit according to claim 13, characterized in that the two resistance elements ( 48 . 49 . 57 . 58 . 63 . 64 ) have a common connection element for power supply and / or power dissipation. Measuring circuit according to claim 14, characterized in that a third circuit branch with a starter ( 52 . 60 . 67 ) connected. Measuring circuit according to one of claims 13 to 15, characterized in that in the first circuit branch a battery ( 51 . 59 . 65 ) and at least one consumer is arranged in the second circuit branch. Measuring circuit according to one of claims 13 to 16, characterized in that in the first circuit branch a battery ( 51 . 59 . 65 ) and in the second circuit branch a generator ( 50 . 66 ) is arranged. Measuring circuit according to claim 14, characterized in that a third circuit branch with a battery ( 59 ' . 65 ' ) connected. Measuring circuit according to claim 18, characterized in that in the first circuit branch a starter ( 67 ' ) and in the second circuit branch a generator ( 66 ' ) is arranged. Measuring circuit according to claim 18, characterized in that in the first circuit branch a parallel connection from a starter ( 60 ' ) and a generator ( 61 ' ) is arranged, while at least one consumer is arranged in the second circuit branch. Measuring circuit according to one of claims 13 to 20, characterized in that the resistor arrangement ( 1 . 1' . 37 . 38 ) is switched on the ground side. Measuring circuit according to one of claims 13 to 21, characterized in that the resistor arrangement ( 1 . 1' . 37 . 38 . 47 . 56 . 62 ) is switched on the voltage side. Measuring circuit according to one of claims 13 to 22, characterized in that the resistor arrangement ( 1 . 1' . 37 . 38 . 47 . 56 . 62 ) is designed according to one of claims 1 to 12.