DE29616313U1 - Electrical component for detecting the flowing electrical current in multi-conductor systems and device for fastening potential connections in measuring resistors - Google Patents

Description

Description

The invention relates to an electrical component for detecting the electrical current in multi-conductor systems and a device for fastening and electrically contacting wire-shaped potential connections in low-resistance measuring resistors in profile or flat conductor form.

Measuring resistors for detecting an electric current flowing through it of a known design consist of a wire- or cuboid-shaped resistance material and are provided with suitable contact structures. DE OS 42 43 349 Production of resistors from composite material describes a measuring resistor that consists of a cuboid-shaped measuring resistor that is connected to a conductor material on two opposite longitudinal edges. A four-pole resistor is achieved by providing connections attached to the conductor materials with soft solder, which can be contacted with a base provided with connection surfaces.

In DE OS 42 36 086 Electrical resistance and method for producing this resistance, an arrangement is described in which the cuboid-shaped measuring resistance is placed in a stamped part and connected to it in an electrically conductive manner. After this assembly, existing webs are separated so that a contactable measuring resistance is available. The potential connections for realizing a four-pole resistance are placed on the stamped part.

The manufacture of such measuring resistors requires compliance with small manufacturing tolerances in order to achieve consistent resistance values. Furthermore, consistent potential tapping conditions cannot be guaranteed, since the resistances of the connection areas between the resistor and the contact structures are included in the measurement.

The amount of heat to be dissipated is limited,

The invention specified in claims 1 and 13 is based on the problem of detecting electrical currents in single and multi-conductor systems with a high cut-off frequency, enabling processing or evaluation of the detected data using electrical means, attaching potential connections to measuring resistors and simultaneously connecting them to them in an electrically conductive manner.

This problem is solved by the features set out in claims 1 and 13.

The invention describes a universally applicable and compact component for detecting flowing electrical currents in multi-conductor systems. This also provides the possibility of designing the component in such a way that the detected parameters are processed or evaluated with one and the same component.

The component consists of at least one resistor and one conductor arrangement, which are arranged parallel to one another. This makes it possible to use the component to record the electrical currents for existing multi-conductor systems, e.g. two-, three- and four-phase systems. The one-piece, cuboid-shaped and low-resistance measuring resistors represent almost purely ohmic resistances. Non-linear inductions are largely avoided. The wave- or trapezoid-shaped elevations in the measuring resistor and/or in the electrical flat conductors mean that, on the one hand, small manufacturing tolerances play no role in the resistance value and, at the same time, there is a gap tapering towards the measuring resistor at the contact points between the electrical flat conductors and the measuring resistor.

which supports the fastening process between the electrical flat conductors and the measuring resistor. By arranging the potential lines directly in the measuring resistor, contact resistance is largely avoided. At the same time, it is possible to place them in the expected main current range in the measuring resistor. The recesses in the measuring resistor are introduced before the resistor arrangement is assembled. A particular advantage here is the fact that the resistance between the potential lines can be predetermined as the distance between the recesses in the measuring resistor, so that a precision measuring resistor can be implemented to measure the electrical current flowing through the resistor arrangement, whereby, for example, fluctuations in the material composition of the measuring resistor are easily compensated. The recesses are therefore advantageously introduced before the measuring resistor is joined to the electrical flat conductors using known non-cutting or cutting processes.

The use of wire-shaped potential lines made of the same material as the measuring resistor avoids the formation of transition resistances in the form of, for example, intermetallic phases at the contact point, so that almost constant conditions are guaranteed even over a longer operating period.

The connection with a multilayer circuit board as a component carrier results in a compact and universally usable component. A middle layer of the multilayer circuit board serves to shield electrical and magnetic fields that arise when current flows through the flat conductors and that influence the processing of the current-equivalent potential. The contacting and assembly of the electrical component takes place directly using the ends of the flat conductors, which are advantageously designed as contacts themselves. The electrical component can thus be mounted on a component carrier or placed in a housing in such a way that the ends of the flat conductors are accessible from the outside and thus

be electrically connected to a mating contact in a detachable or permanent manner.

The device can be used to produce selectable and precise measuring resistors in such a way that it is possible to tap voltage potentials that can be predetermined according to the flowing electrical current and that remain constant within a production series. The use of these measuring resistors significantly reduces the effort required to adapt downstream electrical circuit units. The punching elements are also designed as electrodes, so that two work steps can be carried out with one device. The wire-shaped potential connection is guided and positioned in the pressing tool, so that easy handling and contacting is guaranteed. Additional handling techniques for the wire-shaped potential connection are not required. The press connection ensures a low-resistance connection between the wire-shaped potential connection and the measuring resistor.

Advantageous embodiments of the invention are specified in claims 2 to 12 and 14 to 16. The arrangement of an electrically non-conductive and thermally conductive material between the elevations and between the electrical flat conductor and the measuring resistor according to the development of claim 2 leads on the one hand to an increase in the mechanical stability of the resistor arrangement and on the other hand to a favorable possibility of dissipating waste heat from the measuring resistor itself. The flat surfaces of the electrical flat conductors, which carry the electrically non-conductive and thermally conductive material, are brought together except for a narrow gap and thus serve to dissipate heat from the measuring resistor itself or as a carrier for a suitable heat sink.

The further developments of claims 3 and 4 show various possibilities for connecting the measuring resistor with

the electrical flat conductors. If, in accordance with the further developments of claims 11 and 12, the measuring resistor consists of a metallic resistance material and the electrical flat conductor consists of copper, the use of the electron beam welding process according to claim 4 results in a particularly stable and low-resistance connection. No other materials are introduced, so that constant current paths are present even over a longer period of operation. Advantageous designs of the recesses of the measuring resistor are listed in claim 5.

Transition resistances caused by supplied materials, weld metal, adhesive or solder are avoided by the connection technology of the further development of claim 6. At the same time, consistent measurement results of the potential are ensured over a longer period of time.

The attachment of at least one resistor arrangement and one conductor arrangement to a component carrier according to the further development of claim 7 significantly increases the universal use of the electrical component. On the side of the component carrier opposite the side with the resistor and conductor arrangements, a wide variety of circuit structures can be implemented for recording or processing the measurement results. The component carrier itself consists of the materials used in the electronics industry, so that known and proven structuring and assembly technologies are used for production. The connection of the component carrier to the electrical flat conductors of the resistor arrangement and the conductor arrangement takes place according to the further development of claim 8 using soldering or adhesive processes as positive connections or screw connections as force-locking connection technologies.

The design of the contact pins according to the further development of claim 9 enables reliable and low-resistance clamp connections both in component carriers and through counter contacts located on wires or rails.

the, given.

The further development of protection claim 10 enables the electrical component to be manufactured in very large quantities.

The features listed in the further developments of claims 14 to 16 support the easy handling of the device. The curved surface of the pressing tool deforms the part of the profile or flat conductor enclosed by it as a measuring resistor to form a wire-shaped potential connection and thus ensures a low-resistance contact. The design of the curvature in accordance with the further development of claim 16 supports this process significantly.

Two embodiments of the invention are shown in the drawings.

Show it:

Figure 1 shows a resistor and a conductor arrangement with a component carrier for installation in a commercially available housing for use in two-wire systems,

Figure 2 shows a first variant of the connection of the measuring resistor with the electrical flat conductors of the resistor arrangement,

Figure 3 two resistor and one conductor arrangement with a component carrier for use in a three-wire system as an electrical component for mounting on another component carrier and

Figure 4 shows a second variant of the connection of the measuring resistor with the electrical flat conductors of the resistor arrangement.

A first embodiment of the electrical component according to the illustration in Figure 1 consists of an electrical resistance arrangement 1 and a conductor arrangement 2, which have approximately the same geometric shapes and dimensions.

The resistor arrangement 1 is, on the one hand, a separate electrical flat conductor, so that there are two electrical flat conductors 4a and 4b. These are made of copper. The ends of the electrical flat conductors 4a and 4b at the separation point each have a wave-shaped elevation 5 that runs parallel to the separation point and is designed as a bead. On these elevations, a one-piece, cuboid-shaped and low-ohm measuring resistor 3 made of a metallic resistance material is attached in an electrically conductive manner. This has the dimensions 14.0 x 5.0 x 1.0 mm ³ and an electrical resistance of 1.0 mOhm. The distance between the elevations 5 and the measuring resistor 3 attached to them in an electrically conductive manner determines the electrical resistance value of the resistor arrangement 1. The distance is 8 mm and the electrical resistance of the resistor arrangement is 0.7 mOhm.

Welding (ultrasonic or electron beam welding), soldering or adhesive methods are used for fastening. On the one hand between the wave-shaped elevations 5 and on the other hand between the measuring resistor 3 and the electrical flat conductors 4a and 4b of the resistor arrangement 1 there is a layer 12 in the form of a cuboid-shaped body (Figure 2) which consists of an electrically non-conductive but thermally highly conductive material. In the example, this is a piece of foil made of aluminum oxide ceramic. Only a narrow gap (separation point of the electrical flat conductor of the resistor arrangement) is therefore necessary between the ends of the electrical flat conductors 4a and 4b, since this measure ensures good heat transfer from the measuring resistor 3 via the aluminum oxide ceramic foil to the electrical flat conductors 4a and 4b. At the same time, the mechanical strength of the resistor arrangement 1 increases. Furthermore, additional heat sinks (not shown) can be attached to one of the electrical flat conductors 4a or 4b, so that a significantly higher current flowing through the measuring resistor 3 is detected. In the area of the measuring resistor 3, which is opposite to the area to which the electrical flat conductors 4a and 4b are connected,

Two depressions 6a and 6b are made in the measuring resistor 3. The position of the depressions 6a and 6b is determined before they are made by determining the potential caused by a current flow ¹ between the depressions 6a and 6b to be made, so that constant electrical resistance values are achieved. They have a round cross-section and the end sections of wires 7a and 7b, which consist of the material of the measuring resistor 3, are attached to them. These wires 7a and 7b are used to tap the voltage potential which is established when a current flows through the measuring resistor 3 and is proportional to the current flowing. Both direct and alternating currents can be detected. The wire ends are advantageously cold-pressed to the measuring resistor 3. This ensures high long-term stability with almost constant conditions for the potential tap. The recesses 6a and 6b are spaced 8 mm apart so that, among other things, the following voltages are measured depending on the electrical current flowing in the measuring resistor 3:

Electric current in A 5.0 10.0 20.0 Voltage in mV 3.5 7.0 14.0

An electrical flat conductor 4b of the resistor arrangement 1 is advantageously completely or partially tinned. This is soldered on a conductor side of a known multilayer circuit board 8 in such a way that the measuring resistor 3 is located outside this multilayer circuit board 8. The recesses 6a and 6b with the potential connections are located on the side that is opposite the side of the multilayer circuit board 8 with the electrical flat conductor 4b attached to it. A conductor arrangement 2 made of copper is soldered onto the multilayer circuit board 8 parallel to the resistor arrangement 1. For this purpose, this is also completely or partially tinned. The surface of the multilayer circuit board 8 that is opposite the surface with the resistor 1 and conductor arrangement 2 has a structured copper surface so that conductor tracks 9 and contact surfaces for mounting electrical components 10 are provided.

are present. Electrical components 10 are soldered onto the contact surfaces, so that this part corresponds to a populated electronic circuit board. At the same time, contact surfaces are present for attaching the wires 7a and 7b for the potential to be tapped from the measuring resistor 3. This makes it possible to implement an evaluation or measured value processing circuit. The multi-layer circuit board 8 also has a metallic inner layer 11, which functions as a shield between the resistor 1 and conductor arrangement 2 and the evaluation or measured value processing circuit.

The ends of the resistor 1 and conductor arrangement 2 are designed so that terminal contacts can be plugged in. Of course, the ends can also be designed so that connecting wires can be soldered or screwed on.

The electrical flat conductors 4a and 4b of the resistor arrangement 1, the conductor arrangement 2 and the measuring resistor 3 are advantageously made from preformed strip material.

A second embodiment of the electrical component according to the illustration in Figure 3 consists of two resistor arrangements 1 and a conductor arrangement 2 for detecting the electrical current in a three-conductor system. One of the resistor arrangements 1 is a separate electrical flat conductor made of copper. The ends of the electrical flat conductors 4a and 4b at the separation point each have a wave-shaped elevation 5 running parallel to the separation point, which is designed as a bead. In contrast to the first embodiment, the electrical flat conductors 4a and 4b end directly after the elevations 5 (Figure 2). On the other hand, a one-piece, cuboid-shaped and low-ohm measuring resistor 3 made of a metallic resistance material is attached to these elevations 5. This has the dimensions 14.0 x 5.0 x 1.0 mm ³ and an electrical resistance of 1.2 mOhm. The distance between the elevations 5 and the measuring resistor 3 attached to them in an electrically conductive manner determines the electrical resistance value of the resistor arrangement 1.

Welding (ultrasonic or electron beam welding), soldering or gluing processes are used.

Two recesses 6a and 6b are made in the surface of the measuring resistor 3, which is opposite the surface to which the electrical flat conductors 4a and 4b are connected. The position of the recesses 6a and 6b is determined before they are made by determining the potential caused by a current flow between the recesses 6a and 6b to be made, so that constant potentials can be tapped. The recesses have a round cross-section and an end section of a copper wire 7a or 7b is attached to each of them. These wires 7a and 7b are used to tap the voltage potential, which is established when a current flows through the measuring resistor 3 and is proportional to the current flowing. The wire ends in the recesses 6a and 6b are advantageously cold-pressed with the measuring resistor 3. This ensures high long-term stability with almost constant potential tapping conditions. The recesses 6a and 6b are 8 mm apart, so that the following voltages, among others, are measured depending on the current flowing in the measuring resistor 3: electric current in A 5.0 10.0 20.0 Voltage in mV 3.5 7.0 14.0

The electrical flat conductors 4a and 4b of the resistor arrangements 1 are advantageously fully or partially tinned. They are thus attached to a conductor side of a known multilayer circuit board 8. This has an opening in the middle. The resistor arrangements 1 are placed and soldered in such a way that the measuring resistors 3 are freely accessible in the opening in the multilayer circuit board 8. The recesses 6a and 6b with the potential connections are located on the side that is opposite the side of the multilayer circuit board 8 with the electrical flat conductors 4a and 4b of the resistor arrangements 1 attached to it.

Parallel to the resistor arrangements 1, a conductor arrangement 2 made of copper is soldered onto the multilayer circuit board 8.

For this purpose, it is also completely or partially tinned. The surface of the multilayer circuit board 8, which is opposite the surface with the resistor arrangements 1 and the conductor arrangement 2, has a structured copper surface, so that conductor tracks 9 and contact surfaces for mounting electrical components 10 are present. Electrical components 10 are soldered onto the contact surfaces, so that this part corresponds to a populated electronic circuit board. At the same time, contact surfaces are present for attaching the potential connections of the measuring resistor 3. This makes it possible to implement an evaluation or measurement value processing circuit.

The multilayer circuit board 8 also has a metallic inner layer 11, which acts as a shield between the resistor arrangements 1 and the conductor arrangement 2 and the evaluation or measured value processing circuit.

Contact pins 13 are provided for contacting the electrical component. This means that this component can be mounted on component carriers and contacted.

The different features of the first and second embodiments are interchangeable, so that a large number of embodiments result from the combination of these features.

A third embodiment represents a device for fastening and electrically contacting the wire-shaped potential connections 7 in the measuring resistors 3. The device is explained in more detail below, taking into account the manufacture of the measuring resistors.

The indentations 6 are made in a strip-shaped profile conductor using two needle-shaped punching elements that can be positioned relative to one another and whose diameter is larger than the diameter of the wire-shaped potential connections 7. Before these indentations 6 are made, the voltage drop between the punching elements, which are initially only loosely positioned on the profile conductor, is recorded. This voltage

drop is based on an electrical current flow in the profile conductor. The voltage drop can be specified so that the distance between the punching elements can be adjusted according to the voltage drop. After determining the correct position relative to one another, the recesses 6 are made in the profile conductor using the punching elements.

A pressing element that guides the wire-shaped potential connection 7 inside is then positioned on the recess 6. After the wire-shaped potential connection 7 has been pushed into the recess 6, the profile conductor is plastically formed by pressing the pressing tool against the measuring resistor 3, so that the wire-shaped potential connection 7 is pressed onto the profile conductor.

The hole in the pressing tool that accommodates the potential connection 7 is conically widened towards the profile conductor. The surface facing the profile conductor is curved. This curvature has radii that continuously increase towards the hole, so that the material of the profile conductor is conically deformed to form the wire-shaped potential connection 7. This increases the contact area between the profile conductor and the wire-shaped potential connection 7. The section of the profile conductor provided with the wire-shaped potential connection is separated using the cutting device, so that the measuring resistor 3 is created.

The individual components of the device described are connected to electrical control, electrical evaluation and drive devices, so that the described functionality is provided.

Claims (16)

Protection claims 1. Electrical component for detecting the flowing electrical current in multi-conductor systems, characterized in that at least one electrical resistance arrangement (1) which consists of a one-piece, cuboid-shaped and low-resistance measuring resistor (3) which bridges an electrical and spatial separation point of an electrical flat conductor (4a) and (4b), that the measuring resistor (3) and/or the flat conductor (4a) and (4b) has at least two wave-shaped or trapezoidal elevations (5) running parallel to one another, so that the separation point of the electrical flat conductor (4a) and (4b) is located between the elevations (5) and the distance between the elevations (5) in conjunction with the specific electrical resistance of the material of the measuring resistor (3) determines the electrical resistance of the resistance arrangement (1), that in each case one end section of either high electrical conductivity or consisting of the material of the measuring resistor (3) and formed in the form of a wire (7a) and (7b) are electrically conductively secured one behind the other in at least two depressions (6a) and (6b) in the measuring resistor (3) within at least one of the freely accessible surfaces and the elevations (5) and in the direction of the electrical flat conductors (4a) and (4b), that there is a distance between the depressions (6a) and (6b) and the potential connections (7a) and (7b) secured and contacted therein, which can be set according to the electrical resistance between the depressions (6a) and (6b) to be introduced in the measuring resistor (3) and/or the potential connections (7a) and (7b) secured and contacted therein according to predeterminable electrical resistance parameters or can be selected within the limits between the elevations (5), and an electrical conductor arrangement (2), which is preferably an electrical flat conductor, is arranged parallel to one another, that at least one section of the electrical flat conductor (4b) of the resistor arrangement (1) and the electrical conductor arrangement (2) with a component carrier are mechanically firmly connected so that on the opposite Conductor tracks (9) and electronic and/or electrical components (10) are arranged on the side of the component carrier, that at least one metallic shielding plane (11) is integrated in the component carrier over its entire surface and that the ends of the resistor arrangement (1) and the conductor arrangement (2) themselves are designed as contacts or that the ends are electrically connected to contact pins. 2. Electrical component according to protection claim 1, characterized in that a layer (12) made of an electrically non-conductive and thermally conductive material is located on the one hand between the elevations (5) and on the other hand between the electrical flat conductor (4a) and (4b) and the measuring resistor (3). 3. Electrical component according to claim 1, characterized in that the measuring resistor (3) and the flat conductors (4a) and (4b) of the resistor arrangement (1) are welded, soldered or glued to one another in an electrically conductive manner. 4. Electrical component according to protection claim 3, characterized in that the measuring resistor (3) and the flat conductors (4a) and (4b) of the resistor arrangement (1) are welded together by electron beams. 5. Electrical component according to claim 1, characterized in that the recesses (6a) and (6b) in the measuring resistor (3) are through holes or holes with a depth smaller than the thickness of the measuring resistor (3). 6. Electrical component according to claim 1, characterized in that the end sections of the potential connections (7a) and (7b) are either welded or pressed together with the measuring resistor (3) by plastic deformation. 7. Electrical component according to protection claim 1, characterized in that the component carrier is a structured and copper-clad multilayer circuit board (8) which has at least one conductor structure, that this conductor structure consists of copper and the carrier consists of a glass fiber reinforced epoxy resin hard fabric or a ceramic. 8. Electrical component according to claim 1, characterized in that the flat conductors (4a) and (4b) of the resistor arrangement (1), the conductor arrangement (2) and the component carrier are connected to one another in a form-fitting or force-fitting manner. 9. Electrical component according to claim 1, characterized in that the cross sections of the contact pins are polygonal. 10. Electrical component according to protection claim 1, characterized in that the measuring resistor (3) and the electrical flat conductors (4a) and (4b) of the resistor arrangement (1) and the conductor arrangement (2) are made of strip material. 11. Electrical component according to claim 1, characterized in that the electrical flat conductors (4a) and (4b) of the resistor arrangement (1) and the conductor arrangement (2) consist of copper and are tinned. 12. Electrical component according to protection claim 1, characterized in that the measuring resistor (3) and the potential connections (7a) and (7b) preferably consist of a metallic resistance material. 13. Device for fastening and electrically contacting wire-shaped potential connections in the surfaces of low-resistance measuring resistors in profile or flat conductor form with electrical control, electrical evaluation and drive devices, in particular according to claims 1, 5 and 6, characterized in that two needle-shaped punching elements which detect the voltage drop caused by an electrical current flow through the profile or flat conductor and are designed as electrodes, can be moved relative to one another and can be positioned on the profile or flat conductor and can be contacted with it, that at least one movable pressing tool which can be positioned one after the other to the recesses (6a) and (6b) in the profile or flat conductor with a wire-shaped potential connection (7) guided therein and a cutting device which serves to separate the measuring resistors (3) from the profile or flat conductor are connected to the electrical control, electrical evaluation and drive devices. 14. Device according to protection claim 13, characterized in that the pressing tool has a bore in the line of symmetry, the diameter of which is larger than the diameter of the potential connection (7) and that the diameter of the bore is conically widened towards the measuring resistor (3). 15. Device according to protection claim 14, characterized in that the surface of the pressing tool is curved towards the measuring resistor (3). ·■ * *« «&bgr;&ogr;&ogr; 16. Device according to claim 15, characterized in that the curvature is designed such that continuously or gradually increasing radii to the bore are present.