DE102021003365A1 - Method of manufacturing a current measuring device and current measuring device - Google Patents

Abstract

The invention relates to a method for producing a device (1) for measuring currents, the method comprising the following steps: a) providing a resistor arrangement (2) comprising at least two connection elements (3, 3') and at least one between the connection elements (3 , 3') arranged resistance element (4),b) molding of at least one contact element (5) from the material of at least one connection element (3, 3') or from the material of the resistance element (4), wherein the contact element (5) has one of the Resistor arrangement (2) facing away from the end face (52) and a cavity (53) open there,c) providing a printed circuit board (8) with at least one through hole (9), on the inner surface (91) of which there is electrically conductive material (92). d) positioning the printed circuit board (8) on the resistor arrangement (2) in such a way that the contact element (5) at least protrudes into the through hole (9), e) expanding the contact element ements (5) in the radial direction by means of an expanding means (14), which is inserted into the cavity (53) of the contact element (5), so that an electrically conductive connection between the contact element (5) and the electrically conductive material (92). the inner surface (91) of the through hole (9). The invention further comprises a device for measuring current intensities.

Description

The invention relates to a method for producing a device for measuring current intensities and such a device.

To measure the current in electronic circuits, measuring resistors are used, which are connected in series with the component to be monitored. The current strength is determined from the voltage drop across the measuring resistor known as the shunt resistor. For example, the correct and reliable measurement of the current intensity is particularly important in a battery management system of an electric or hybrid vehicle. A resistor arrangement that includes such a low-impedance measuring resistor of approximately 10 to 50 μΩ and connection elements for connecting the resistor arrangement to the circuit can be produced from a longitudinally welded composite material. This is for example from the reference EP 0 605 800 A1 famous. The composite material is made from three metal bands, in that the individual metal bands are each connected to one another via a longitudinal seam using an electron beam or laser welding process.

The voltage drop across a measuring resistor is tapped off via contact pins or similar elements that are arranged on the connecting elements on both sides of the measuring resistor. Such contact pins can be soldered, pressed or welded onto the connection elements of the resistor arrangement. The voltage is recorded and processed by measurement and evaluation electronics. Electronic components are provided for this purpose, which can be arranged on a printed circuit board. The printed circuit board can be located in the immediate vicinity of the resistor arrangement.

From the pamphlet DE 10 2009 031 408 A1 a resistor arrangement with a low-impedance current measuring resistor is known. In this resistor arrangement, connection contacts are provided for tapping off the voltage, which are formed by embossing and thread forming in the plate-shaped sections, which are used to connect the resistor arrangement to the external circuit. The measuring lines for voltage measurement are connected to the connection contacts using cable lugs and fastening screws.

Furthermore, from the pamphlet U.S. 10,163,553 B2 a resistance arrangement with two plate-shaped elements for connecting the resistance arrangement to an external circuit and a strip-shaped resistance element is known. There is a hole in each of the two connection elements on both sides of the resistance element, into which a contact pin is inserted. The contact pins are separate components that must be specially manufactured and added to the resistor assembly.

In the devices known from the prior art, it is necessary to use additional components in order to tap off the voltage drop across the measuring resistor. This requires additional effort and costs. Furthermore, contact voltages can occur at the contact points of the individual components, which can falsify the voltage signal.

The invention is based on the object of specifying an improved, in particular simpler and more cost-effective method for producing a device for measuring current intensities and such a device.

The invention is represented by the features of claim 1 in relation to a method and by the features of claim 9 in relation to an apparatus. The further dependent claims relate to advantageous developments and further developments of the invention.

1. a) Bereitstellen einer Widerstandsanordnung umfassend mindestens zwei Anschlusselemente, durch welche eine Stromrichtung festgelegt wird, und mindestens ein in Bezug auf die Stromrichtung zwischen den Anschlusselementen angeordnetes Widerstandselement, wobei das mindestens eine Widerstandselement einerseits und die Anschlusselemente andererseits aus unterschiedlichen, elektrisch leitenden Materialien bestehen,
2. b) Herausformen mindestens eines Kontaktelements aus dem Material mindestens eines Anschlusselements oder aus dem Material des Widerstandselements, wobei das Kontaktelement eine Längsachse aufweist, durch die eine axiale Richtung und eine hierzu senkrechte radiale Richtung definiert werden, und wobei das Kontaktelement so geformt wird, dass es eine von der Widerstandsanordnung abgewandte Stirnseite und einen Hohlraum aufweist, der auf der von der Widerstandsanordnung abgewandten Stirnseite des Kontaktelements offen ist,
3. c) Bereitstellen einer Leiterplatte, welche mindestens eine Durchgangsbohrung mit einer inneren Oberfläche aufweist, auf der sich elektrisch leitendes Material befindet,
4. d) Positionieren der Leiterplatte auf der Widerstandsanordnung derart, dass die Leiterplatte eine von der Widerstandsanordnung abgewandte Oberseite aufweist und dass das mindestens eine Kontaktelement in die Durchgangsbohrung zumindest hineinragt,
5. e) Aufweiten des Kontaktelements in radialer Richtung mittels eines Aufweitmittels, das in axialer Richtung in den Hohlraum des Kontaktelements eingeführt wird, so dass eine elektrisch leitende Verbindung zwischen dem Kontaktelement und dem elektrisch leitenden Material auf der inneren Oberfläche der Durchgangsbohrung hergestellt wird.

The invention relates to a method for producing a device for measuring current intensities using a resistor arrangement, the method comprising the following steps:

1. a) providing a resistor arrangement comprising at least two connection elements, by means of which a current direction is determined, and at least one resistance element arranged between the connection elements with regard to the current direction, the at least one resistance element on the one hand and the connection elements on the other hand consisting of different, electrically conductive materials,
2. b) Shaping out at least one contact element from the material of at least one connection element or from the material of the resistance element, the contact element having a longitudinal axis which defines an axial direction and a radial direction perpendicular thereto, and the contact element being shaped in such a way that it has an end face remote from the resistor arrangement and a cavity which is open on the end face of the contact element remote from the resistor arrangement,
3. c) providing a printed circuit board which has at least one through hole with a has an inner surface on which there is electrically conductive material,
4. d) Positioning the printed circuit board on the resistor arrangement in such a way that the printed circuit board has an upper side facing away from the resistor arrangement and that the at least one contact element at least protrudes into the through hole,
5. e) Expanding the contact element in the radial direction by means of an expanding agent that is introduced into the cavity of the contact element in the axial direction, so that an electrically conductive connection is established between the contact element and the electrically conductive material on the inner surface of the through hole.

The measurement of current strengths is also understood to mean the measurement of the strength of an electrical current that may change over time. The resistor arrangement described above can include a shunt resistor with a resistance of 10 to 50 μΩ as the resistance element. Both the resistance element and the connection elements consist of electrically conductive materials. In this case, the specific electrical resistance of the material of the resistance element is significantly greater, typically at least a factor of 10 greater, than the specific electrical resistance of the material of the connection elements. On the other hand, the absolute value of the temperature coefficient of resistance of the material of the connection elements is very much greater, typically at least a factor of 80 greater than the absolute value of the temperature coefficient of resistance of the material of the resistance element. Typically, the temperature coefficient of resistance of the resistive element material is less than ±5*10 ^-5 1/K, while the temperature coefficient of resistance of the terminal element material is approximately ±4*10 ^-3 1/K. The connecting elements of the resistor arrangement can consist in particular of copper, a preferably low-alloy copper alloy, aluminum or a preferably low-alloy aluminum alloy or can comprise at least one of these materials. The resistance element may be made of a copper alloy which is commonly used as a resistance alloy.

The connection elements can be terminal connection elements of the resistor arrangement. However, it is also possible for at least one connection element to be arranged between two resistance elements in relation to a possible current path. The resistor arrangement can be formed in a planar arrangement. In this case, the connection elements and the at least one resistance element are formed as plate-shaped or strip-shaped elements and are arranged next to one another in one plane, preferably in a row. The thickness of the resistance element or the resistance elements can be arbitrary. However, it is usually not greater than the thickness of the connecting elements.

A contact element is understood to mean a material projection that rises above the otherwise undeformed surface of a connection element or the resistance element. The contact element is formed by shifting material of a connection element or material of the resistance element essentially in the direction perpendicular to the surface of the connection element or of the resistance element. The direction in which the material is displaced defines an axial direction parallel to the longitudinal axis of the contact element and a radial direction perpendicular thereto. The contact element is formed in such a way that it has an end face remote from the resistor arrangement and a cavity which is open on the end face of the contact element which faces away from the resistor arrangement. The contact element is therefore at least partially hollow and the cavity extends from the end face of the contact element in the axial direction into the contact element. In the radial direction, the cavity is delimited by a peripheral, closed wall made of displaced material of a connection element or the resistance element. In this area, the contact element is therefore in the form of a sleeve which is open on at least one side. The cavity is preferably closed on the diametrically opposite side, so that the contact element has a shape similar to a cup in this area. The height of the contact element is at least 0.5 mm, preferably at least 1 mm.

The outer shape of the contact element can be arbitrary, preferably circular, rectangular, square or hexagonal. The contact element preferably has a circular cross-section in the region of the cavity. The shape and/or size of the cross section of the contact element can be constant or change continuously or discontinuously along the longitudinal axis of the contact element. For example, the contact element can have a slightly conical contour, that is to say a contour with boundary surfaces that are slightly inclined relative to the surface of the connecting element or the resistance element. Furthermore, the contact element can be formed in such a way that it has a shoulder. A shoulder is understood as meaning a discontinuous, ie abrupt, change in the cross-sectional shape and/or the cross-sectional size of the contact element. The paragraph can serve as a support for a printed circuit board.

The contact element can be used, preferably together with a further contact element, as a voltage tap for measuring the electrical voltage drop across the resistance element. If the contact element is formed from the material of the resistive element, it can be used as a voltage pickup for measuring the electrical voltage drop across a part of the resistive element. Alternatively, the contact element can also be used to ground the resistor arrangement. One or more such contact elements are preferably formed in all connection elements of the resistor arrangement. The contact elements used for voltage measurement are positioned as close as possible to the resistance element at which the voltage drop is to be determined.

In the context of the present invention, a printed circuit board is understood to mean a flat, plate-shaped or strip-shaped component that is suitable for conducting electrical signals in an electrically conductive material. A flat component is in the form of a plate or strip if two opposite surfaces of the component are plane-parallel to one another. The distance between these two surfaces defines the thickness of the component. A printed circuit board can be, for example, a strip of metal or a plate made of a non-conductive material with conductor tracks applied to its surface. Boards of this type are known by the term "printed circuit board". The printed circuit board has at least one through-hole with an inner surface bearing electrically conductive material. This also includes the case where the printed circuit board is a metal strip or a metal plate, so that there is inherently electrically conductive material on the inner surface of the through-hole. If the printed circuit board is a plate made of non-conductive material with conductor tracks applied to its surface, the electrically conductive material on the inner surface of the through-hole can be connected to a conductor track which is preferably arranged on the side of the circuit board remote from the resistor arrangement. Furthermore, electrical components can be arranged on such a printed circuit board, which are used to measure and evaluate electrical signals. The term through hole refers to a recess in the printed circuit board that extends over the entire thickness of the printed circuit board. The through hole may have a cylindrical shape. Alternatively, a conical shape is also possible.

The printed circuit board is positioned on the resistor arrangement in such a way that the at least one contact element at least protrudes into the through hole. The printed circuit board is positioned essentially plane-parallel to the resistor arrangement, so that the printed circuit board has an upper side facing away from the resistor arrangement and an underside facing the resistor arrangement. There may be a gap between the circuit board and the resistor assembly. However, it is also possible for the printed circuit board to lie directly on the resistor arrangement. The contact element should protrude into the through hole of the printed circuit board by at least half the thickness of the printed circuit board, preferably at least up to 70% of the thickness of the printed circuit board.

The contact element is then expanded in the radial direction using a suitable expansion means. For this purpose, the expanding means is introduced into the cavity of the contact element in the axial direction, starting from the upper side of the printed circuit board. The expansion means is designed in such a way that it can expand the contact element in the radial direction in the region of the cavity. For this purpose, the material of the contact element, which delimits the cavity in the radial direction, is shifted outwards in the radial direction to such an extent that it comes into contact with the inner surface of the through hole of the printed circuit board. In this way, an electrically conductive connection is established between the contact element and the electrically conductive material on the inner surface of the through hole. The enlargement of the outer dimension of the contact element brought about by the widening is preferably between 2% and 15% of its outer dimension before the widening. The widening also reduces the wall thickness of the contact element. A reduction of at least 20% of the original wall thickness is favourable. The expansion means can be a suitable tool that is removed from the cavity of the contact element again after expansion.

The advantage of the method described is that no additional components and/or materials are required to establish the connection between the resistor arrangement and the printed circuit board. Because the contact element is formed directly from the material of a terminal element or the resistance element, it is not necessary to separately mount the contact element on the resistor assembly or on the printed circuit board. The work steps required for this and the required materials, such as solder, are eliminated. Several contact elements can be formed at the same time. The monolithic connection between the contact element and the connection element or between the contact element and the resistance element avoids unwanted contact stresses that can falsify a measurement.

A particularly advantageous aspect of the proposed method is the radial expansion of the contact element by a suitable expanding agent. Because the expansion means is introduced into the cavity of the contact element, the connection between the contact element and the printed circuit board takes place essentially in the area of the through hole. It is therefore not necessary for the contact element to protrude beyond the printed circuit board, that is to say to protrude beyond the top side of the printed circuit board. To form the contact element, the material of the connection element or of the resistance element therefore only has to be deformed to a small extent. The forces required are small. This is advantageous in terms of tool life and process speed. The proposed method can be used particularly advantageously if one or more contact elements are to be formed from the resistance element. The material of the resistance element is usually more difficult to deform than the material of the connection elements. The less it needs to be deformed, the easier the process.

The expansion means can also be a body that remains permanently in the cavity of the contact element. Such a body can be a plug or a rivet, for example. Such a body produces a particularly reliable and permanent contact between the contact element and the inner surface of the through hole of the printed circuit board.

If the resistor arrangement is produced by being cut to length from a longitudinally welded, strip-shaped composite material, then the contact elements can preferably be formed at the same time as the composite material is cut to length. In this case, therefore, steps a) and b) of the method take place simultaneously. A separate, additional work step for forming the contact elements is therefore not necessary. The method is therefore quicker and cheaper than if the contact elements are only formed after the composite material has been cut to length. Furthermore, a high positional accuracy of the contact elements is achieved in this way.

Within the scope of one embodiment of the invention, the expansion means can be designed in such a way that the contact element is expanded by the introduction of the expansion means. The contact element is thus already being expanded in the radial direction during the introduction of the expansion means into the cavity. For this purpose, the expanding means has at least partially a conical outer contour. This outer contour leads to a radial displacement of the material of the contact element when the expansion means is introduced into the cavity. This enables short processing times.

Within the scope of an alternative embodiment of the invention, the expansion means can be designed in such a way that the contact element is expanded after the introduction of the expansion means. The contact element is thus essentially expanded in the radial direction only after the expansion means has been introduced into the cavity. For this purpose, the expanding means has a section whose outside diameter is smaller than the inside diameter of the cavity. This section of the expanding means is then introduced into the cavity without significant resistance and thus also without undesired deformation of the contact element. After the expansion means has been introduced, the contact element is radially expanded by means of a suitable mechanism. If the expanding means is a tool, this can be done, for example, by spreading the tool, by rotating the tool eccentrically, or by electromagnetic forces

Within the scope of a preferred embodiment of the invention, a non-positive connection between the inner surface of the through hole of the printed circuit board and the contact element can also be produced at the same time by the expansion in method step e). For this purpose, the widening of the contact element takes place to such an extent that the material is pressed against the inner surface of the through hole of the printed circuit board so strongly that a press fit is formed. The wall thickness of the contact element is preferably reduced by at least 40%. By forming the press fit, other means for mechanically fixing the printed circuit board on the resistor arrangement can be saved.

Within the scope of a special configuration of this embodiment of the invention, a positive connection between the inner surface of the through hole of the printed circuit board and the contact element can also be produced at the same time by expanding in method step e). For example, the through-hole of the printed circuit board can have a conical shape and be designed in such a way that the inner diameter increases from the bottom of the printed circuit board to the top of the latter. When using an expansion means with an adapted conical outer contour, the expansion of the contact element leads to a positive connection. Such a connection represents a particularly secure type of connection.

Within the scope of a preferred embodiment of the invention, the contact element can have a height that is selected such that after the printed circuit board has been positioned, the end face of the contact element that faces away from the resistor arrangement is within the through-hole on the circuit board or flush with the top of the circuit board. The height designates the extension of the contact element in the axial direction, measured from the non-deformed surface of the connection element or the resistance element. The height is dimensioned in such a way that the depth of penetration of the contact element into the through-hole of the printed circuit board is at most equal to the thickness of the printed circuit board. In other words, in this embodiment the contact element does not project beyond the top side of the printed circuit board. A contact element of such a small height can be formed particularly favorably. Within the scope of a special configuration of this embodiment of the invention, the depth of penetration of the contact element into the through hole of the printed circuit board can be 80 to 100% of the thickness of the printed circuit board. This represents an optimum between the effort required to form the contact element and the quality of the contact between the contact element and the printed circuit board.

Within the scope of a further embodiment of the invention, the contact element can be formed in method step b) by an embossing step or by extrusion. Embossing and extrusion are particularly suitable for forming contact elements that are monolithically connected to the material of the connection elements or the resistance element and extend essentially perpendicularly to the surface of the connection elements or the resistance element. The material is formed using a stamp and a suitable negative mold.

Within the scope of a special configuration of this embodiment of the invention, a negative mold with at least one recess corresponding to the outer contour of the contact element and at least one inner tool positioned in the recess can be used to form the cavity for shaping the contact element, with the inner tool being moved in the direction during process step b). the longitudinal axis of the contact element is moved relative to the recess. This has proven to be a particularly favorable process control in terms of forming technology, so that contact elements with a great height can be produced.

Within the scope of a further special embodiment of the invention, the widening of the contact element in method step e) can be assisted by heating the material of the contact element by means of ultrasound or by means of a laser. The material of the contact element is solidified and hard due to the deformation in method step b). This is a hindrance for the subsequent deformation in step e). By applying heat by means of a laser or by means of ultrasound, the material of the contact element can be heated to such an extent that it is at least partially softened, ie becomes softer. The deformation in step e) is then easier.

With regard to further technical features and advantages of the method according to the invention, reference is hereby explicitly made to the following explanations in connection with a device for measuring current intensities and to the figures and the description of the figures.

A further aspect of the invention relates to a device for measuring current intensities. This also includes the measurement of the strength of an electrical current that may change over time. The device comprises a resistor arrangement and a printed circuit board mechanically and electrically connected to the resistor arrangement. The resistor arrangement comprises at least two connection elements, which define a current direction, and at least one resistance element arranged between the connection elements with respect to the current direction, the at least one resistance element on the one hand and the connection elements on the other hand consisting of different, electrically conductive materials. The printed circuit board has at least one through-hole with an inner surface bearing electrically conductive material. The resistor assembly includes at least one contact element having a longitudinal axis, which is monolithically connected to one of the terminal elements and machined from the material of the terminal element, or which is monolithically connected to the resistive element and machined from the material of the resistive element. The resistor arrangement is electrically and mechanically connected to the printed circuit board by this contact element, in that the contact element at least protrudes into the through-hole of the printed circuit board and is non-positively connected to the electrically conductive material on the inner surface of the through-hole. For this purpose, the contact element has an end face remote from the resistor arrangement and a cavity which is open on the end face of the contact element remote from the resistor arrangement. At the transition from its end face to the cavity, the contact element has a conical contour.

With regard to the terms used to describe the device, reference is hereby made explicitly to the above explanations of the terms in connection with the description of the method for producing a device for measuring current intensities.

The particular advantage of the device described is that the monolithic connection between the contact element and the connection element or resistance element avoids unwanted contact stresses that can falsify a measurement. Furthermore, the device can be manufactured inexpensively and with high precision because the contact element is formed directly from the material of the connection element or the resistance element. A particularly advantageous aspect of the device described is the non-positive connection between the printed circuit board and the resistor arrangement. This connection is established by the contact element, which is brought into electrical and mechanical contact with the inner surface of the through-hole of the printed circuit board by means of a widening process. In order to carry out this expansion process, the contact element has an end face which is remote from the resistor arrangement and a cavity which is open on the end face of the contact element which is remote from the resistor arrangement. At the transition from its end face to the cavity, the contact element has a conical contour. This conical contour is the result of the expansion process and can serve to facilitate the introduction of an expansion means into the cavity of the contact element.

Within the scope of one embodiment of the invention, the contact element can have a height that is selected such that the end face of the contact element facing away from the resistor arrangement is located within the through-hole of the printed circuit board or is flush with the top side of the printed circuit board. The height designates the extent of the contact element in the direction of its longitudinal axis, measured from the non-deformed surface of the connection element or the resistance element. The height is dimensioned in such a way that the depth of penetration of the contact element into the through-hole of the printed circuit board is at most equal to the thickness of the printed circuit board. In other words, the contact element does not project beyond the top side of the printed circuit board. A contact element with this low height can be shaped particularly favorably. Within the scope of a special configuration of this embodiment of the invention, the depth of penetration of the contact element into the through hole of the printed circuit board can be 80 to 100% of the thickness of the printed circuit board. This represents an optimum between the effort required to form the contact element and the quality of the contact between the contact element and the printed circuit board.

Within the scope of an advantageous embodiment of the device, the at least one contact element can have a shoulder on which the printed circuit board rests in such a way that the printed circuit board is at a distance from the connection element and thus from the resistor arrangement. The distance between the printed circuit board and the resistor arrangement results in better thermal decoupling of the printed circuit board from the resistor arrangement. In this case, the heat that is generated when current flows through the resistance element cannot be transferred directly from the resistance element or from a connection element to the printed circuit board, but the heat must flow through the contact element. Due to its relatively small cross section, the contact element represents a large thermal resistance. The heat flow from the resistor arrangement to the printed circuit board is therefore reduced and the printed circuit board remains at a lower temperature level than if the printed circuit board were to rest directly on a connection element. This embodiment is particularly advantageous when the thickness of the resistance element is not less than the respective thickness of the connection elements.

In an advantageous embodiment of the invention, the surface of the at least one contact element can have a metallic coating, in particular a coating containing tin, silver or nickel. Such a coating prevents corrosion and can thus ensure that the electrical contact between the contact element and the electrically conductive material on the inner surface of the through hole is of high quality over the entire service life of the device. The coating can have been applied in step b) before the contact element is formed, or the contact element can have been coated in a separate step between method steps b) and c).

With regard to further technical features and advantages of the device according to the invention, explicit reference is made to the explanations in connection with the method according to the invention described above and to the figures and the description of the figures.

Exemplary embodiments of the invention are explained in more detail with reference to the schematic drawings.

• 1 eine Schrägansicht einer Widerstandsanordnung
• 2 eine Seitenansicht einer Widerstandsanordnung
• 3 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung bei Abschluss von Verfahrensschritt b)
• 4 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung mit geformtem Kontaktelement
• 5 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung mit darauf positionierter Leiterplatte
• 6 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung während Verfahrensschritt e)
• 7 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung mit darauf fixierter Leiterplatte
• 8 in Schnittansicht einen Ausschnitt aus einer Widerstandsanordnung mit darauf fixierter Leiterplatte und mit Kontaktelement mit Absatz

Show in it:

• 1 an oblique view of a resistor arrangement
• 2 a side view of a resistor arrangement
• 3 in a sectional view a section of a resistor arrangement upon completion of method step b)
• 4 in a sectional view a section of a resistor arrangement with a shaped contact element
• 5 in sectional view a section of a resistor arrangement with a printed circuit board positioned on it
• 6 in a sectional view a section of a resistor arrangement during method step e)
• 7 in a sectional view a section of a resistor arrangement with a printed circuit board fixed thereon
• 8th in a sectional view a section of a resistor arrangement with a printed circuit board fixed thereon and with a contact element with a shoulder

Corresponding parts are provided with the same reference symbols in all figures.

1 shows an oblique view of a resistor arrangement 2 without a contact element. The resistor arrangement 2 has two terminal connection elements 3, 3' and a resistance element 4 which is positioned between the two connection elements 3, 3'. The connection elements 3, 3' and the resistance element 4 each have a plate-like shape. The thickness of the resistance element 4 is slightly less than the respective thickness of the two connection elements 3, 3'. The resistor arrangement 2 can be connected to a circuit at the two connection elements 3, 3'. For this purpose, the two connecting elements 3, 3′ can have connecting devices, for example bores, which are not shown. These connection devices are each attached in the area of the connection elements 3, 3' which is remote from the resistance element 4. The resistance element 4 is located between the connection elements 3, 3' in relation to the direction of the current flow. When current flows, an electrical voltage drops across the resistance element 4, on the basis of which the strength of the current flowing through the resistance arrangement 2 can be determined.

2 shows a side view of the resistor arrangement 2 according to FIG 1 . A resistor arrangement 2 as in 1 and 2 shown can be produced in a known manner by longitudinal seam welding of three strips to form a composite material and then cutting the welded composite material to length.

3 shows a sectional view of an enlarged section of the resistor arrangement 2 according to FIG 1 and 2 upon completion of method step b). A negative mold 12 with a recess 121 and an inner tool 122 arranged in the recess 121 was positioned on the upper side of the connection element 3 . On the underside of the connecting element 3, a stamp 11 has penetrated the material of the connecting element 3, which is symbolized by the arrow pointing upwards. The punch 11 is positioned so that it faces the recess 121 of the negative mold 12 . The penetration of the punch 11 deformed the material of the connection element 3 essentially perpendicularly to the surface of the connection element 3 and was displaced into the empty space of the negative mold 12 which is defined by the recess 121 and the inner tool 122 . In this way, a material projection that forms the contact element 5 was formed. The inner tool 122 causes the contact element 5 to have a cavity open on one side after the inner tool 122 has been removed.

4 shows a sectional view of an enlarged section of the resistor arrangement 2 with a shaped contact element 5 after method step b). The stamp 11 and the negative mold 12 have been removed. In order to facilitate the removal of the stamp 11 and the negative mold 12, the stamp 11, the recess 121 and the inner tool 122 in the negative mold 12 can each have a contour with bevels for demoulding. Accordingly, the shaped contact elements 5 can also have a contour with bevels. The angle that the bevels form with the normal to the surface of the connection elements 3 for demoulding is typically approximately 2°. Due to this slight deviation from the normal, the slants are not shown explicitly in the figures.

The contact element 5 has a longitudinal axis A, which is oriented perpendicular to the surface of the connection element 3 . Furthermore, the contact element 5 has an end face 52 which faces away from the connection element 3 and thus from the resistor arrangement 2 . Starting from this end face 52, a cavity 53 extends along the longitudinal axis A of the contact element 5. In the case shown, this cavity 53 extends approximately to the undeformed surface of the connecting element 3. For manufacturing reasons, however, it can be advantageous to shape the contact element 5 in this way that the cavity 53 extends less far into the contact element 5 or, alternatively, that the cavity 53 extends into the material of the connection element 3 . Due to the cavity 53, the contact element 5 has the shape of a sleeve which is closed on one side and open on the other side. The height of the contact element 5 is marked with the H symbol. The height H is measured starting from the non-deformed surface of the connection element 3 up to the end face 52 of the contact element 5 .

The contact element 5 is provided for tapping the electrical voltage drop across the resistance element 4 . In order to minimize falsifications of the measured value, the contact element 5 was formed from the connection element 3 in such a way that it is positioned close to the connection point between the connection element 3 and the resistance element 4 .

5 shows a sectional view of the enlarged section of the resistor arrangement 2 according to FIG 4 additionally with a printed circuit board 8 of thickness D positioned on the resistor arrangement 2. 5 thus represents the resistor arrangement 2 and the printed circuit board 8 according to method step d). On the inner surface 91 of the through hole 9 of the circuit board 8 is electrically conductive material 92, which is not shown in detail for reasons of clarity. The printed circuit board 8 was positioned in such a way that the contact element 5 protrudes into the through hole 9 up to a penetration depth T. In the case shown, the penetration depth T is slightly less than the thickness D of the printed circuit board 8 so that the end face 52 of the contact element 5 is not flush with the upper side 81 of the printed circuit board 8 but is still within the through hole 9 . The penetration depth T is approximately 90% of the thickness D of the printed circuit board 8. The clear width of the through hole 9 is slightly larger than the outer dimensions of the contact element 5. In the exemplary embodiment shown, the printed circuit board 8 does not lie directly on the connecting element 3, which is due, for example, to shown spacers can be achieved. A large distance between the printed circuit board 8 and the resistance element 4 is advantageous because this allows heat generated in the resistance element to be dissipated quickly. Electronic components that may be present on the printed circuit board 8 are not shown for reasons of clarity.

6 shows a sectional view of the enlarged detail of the resistor arrangement 2 during method step e). An expanding means 14 with a conical shape is introduced into the cavity 53 of the contact element 5 in the direction of the arrow. The outer dimensions of the expansion means 14 are selected such that the material of the contact element 5 is displaced outwards in the radial direction, ie towards the inner surface 91 of the through hole 9 , due to the conical shape of the expansion means 14 . As a result, the contact element 5 comes into contact with the electrically conductive material 92 on the inner surface 91 of the through hole 9, forming an electrically conductive connection. This in 6 The expanding means 14 shown can be a body that remains in the cavity 53 of the contact element 5, or it can be the working area of a tool that is removed from the cavity 53 of the contact element 5 after the expansion.

7 shows a sectional view of the enlarged section of the resistor arrangement 2 according to FIG 6 after removing the tool used for expanding. 7 11 thus simultaneously represents the sectional view of a part of a device 1 for measuring current intensities by means of the resistor arrangement 2.

8th 1 shows a sectional view of part of a device 1 for measuring current levels with a resistor arrangement 2 and a printed circuit board 8 positioned on the resistor arrangement 2. The contact element 5 has a circumferential shoulder 51 on which the printed circuit board 8 rests. For this purpose, the contact element 5 is designed in such a way that the outer dimension of the contact element 5 in the partial area that directly adjoins the connection element 3 is larger than the clear width of the through hole 9 of the printed circuit board 8 . Thus, the printed circuit board 8 does not rest on either the connecting element 3 or the resistance element 4, even without additional spacers. When forming the contact element 5 from the material of the connecting element 3, the height of the shoulder 51 has already been taken into account. The circuit board 8 is contacted by the contact element 5 in the same way as in FIG 6 illustrated and related to 6 illustrated embodiment.

For reasons of better representation, the invention in the 1 until 8th explained by way of example using a resistor arrangement 2, which comprises only one resistor element 4 and two terminal connection elements 3, 3'. It is also possible to apply the method described above to resistor arrangements which have two or more resistor elements and at least one additional connection element arranged between two resistor elements with respect to a possible current path. The resistor arrangement can be configured in such a way that the same current flows through at least two resistor elements, which enables a redundant current measurement, or that different currents flow through at least two resistor elements, which enables partial currents to be measured. The basis of the above description, based on the 1 until 8th and methods for forming contact elements 5 and for making an electrical connection with a printed circuit board 8, explained using the exemplary embodiments, can also be used in these cases for forming one or more contact elements 5 from the material of one between two wider state elements arranged connection element are used.

Reference List

1

contraption

2

resistor assembly

3, 3'

connection element

4

resistance element

5

contact element

51

Unit volume

52

face

53

cavity

8th

circuit board

81

top

9

through hole

91

inner surface

92

electrically conductive material

11

Rubber stamp

12

negative form

121

recess

122

inner tool

14

expanding agent

A

longitudinal axis

H

Height

T

penetration depth

D

thickness

QUOTES INCLUDED IN DESCRIPTION

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

Patent Literature Cited

• EP 0605800 A1 [0002]
• DE 102009031408 A1 [0004]
• US10163553B2 [0005]

Claims (12)

Method for producing a device (1) for measuring the strength of an electric current by means of a resistor arrangement (2), the method comprising the following steps: a) Providing a resistance arrangement (2) comprising at least two connection elements (3, 3') and at least one resistance element (4) arranged between the connection elements (3, 3') with respect to the direction of the electric current, wherein the at least one resistance element ( 4) on the one hand and the connection elements (3, 3') on the other hand consist of different, electrically conductive materials, b) Forming of at least one contact element (5) from the material of at least one connection element (3, 3') or from the material of the resistance element (4), wherein the contact element (5) has a longitudinal axis (A) through which an axial direction and a radial direction perpendicular thereto can be defined, and wherein the contact element (5) is shaped in such a way that it has an end face (52) facing away from the resistor arrangement (2) and a cavity (53) which is on the end of the resistor arrangement (2) facing away from the end face (52) of the contact element (5) is open, c) providing a printed circuit board (8) which has at least one through hole (9) with an inner surface (91) on which electrically conductive material (92) is located, d) Positioning the circuit board (8) on the resistor arrangement (2) in such a way that the circuit board (8) has an upper side (81) facing away from the resistor arrangement (2) and that the at least one contact element (5) fits into the through hole (9) at least protrudes e) expanding the contact element (5) in the radial direction by means of an expanding means (14), which is inserted in the axial direction into the cavity (53) of the contact element (5), so that an electrically conductive connection between the contact element (5) and the electrically conductive material (92) is produced on the inner surface (91) of the through hole (9). procedure after claim 1 , characterized in that the expansion means (14) is designed in such a way that the expansion of the contact element (5) takes place by the introduction of the expansion means (14). procedure after claim 1 , characterized in that the expansion means (14) is designed so that the expansion of the contact element (5) takes place after the insertion of the expansion means (14). Procedure according to one of Claims 1 until 3 , characterized in that by expanding in method step e) a non-positive connection between the inner surface (91) of the through hole (9) of the printed circuit board (8) and the contact element (5) is produced. Procedure according to one of Claims 1 until 4 , characterized in that the contact element (5) has a height (H) which is selected such that after the positioning of the printed circuit board (8) the end face (52) of the contact element (5) facing away from the resistor arrangement (2) is inside the through hole (9) of the printed circuit board (8) is located or flush with the top (81) of the printed circuit board (8). Procedure according to one of Claims 1 until 5 , characterized in that the shaping of the contact element (5) in method step b) takes place by an embossing step or by extrusion. procedure after claim 6 , characterized in that for shaping the contact element (5) a negative mold (12) with at least one recess (121) corresponding to the outer contour of the contact element (5) and at least one inner tool (122) positioned in the recess (121) for shaping the Cavity (53) is used and that during step b) the inner tool (122) is moved in the direction of the longitudinal axis (A) of the contact element (5) relative to the recess (121). Method according to one of the preceding claims, characterized in that the widening of the contact element (5) in method step e) is supported by heating the material of the contact element (5) by means of ultrasound or by means of a laser. Device (1) for measuring the strength of an electric current, comprising a resistor arrangement (2) and a printed circuit board (8) mechanically and electrically connected to the resistor arrangement (2), the resistor arrangement (2) having at least two connection elements (3, 3') and at least one resistance element (4) arranged between the connection elements (3, 3') with respect to the direction of the current, the at least one resistance element (4) on the one hand and the connection elements (3, 3') on the other hand being made of different, electrically conductive materials exist, and wherein the printed circuit board (8) has at least one through hole (9) with an inner surface (91) on which electrically conductive material (92) is located, characterized in that the resistor arrangement (2) has at least one Contact element (5) with a longitudinal axis (A), which is monolithically connected to one of the connection elements (3, 3') and machined from the material of the connection element (3, 3') or which is monolithically connected to the resistance element (4) and is machined from the material of the resistance element (4), and through which the resistance arrangement (2) is connected to the printed circuit board (8) in an electrically conductive and mechanical manner, in that the contact element (5) penetrates the through hole (9) in the printed circuit board (8) at least protrudes and is non-positively connected to the electrically conductive material (92) on the inner surface (91) of the through hole (9), the contact element (5) having an end face (52) remote from the resistor arrangement (2) and a cavity (53) which is open on the end face (52) of the contact element (5) facing away from the resistor arrangement (2), and wherein the contact element (5) at the transition from its end face (52) to the cavity space (53) has a conical contour (54). Device (1) after claim 9 , characterized in that the contact element (5) has a height (H) which is chosen such that the resistor arrangement (2) facing away from the end face (52) of the contact element (5) within the through hole (9) of the printed circuit board ( 8) is located or flush with the top (81) of the printed circuit board (8). Device (1) after claim 9 or 10 , characterized in that the at least one contact element (5) has a shoulder (51) on which the printed circuit board (8) rests in such a way that the printed circuit board (8) is spaced from the resistor arrangement (2). Device (1) according to one of claims 9 until 11 , characterized in that the at least one contact element (5) has a surface with a metallic coating, in particular a coating containing tin, silver or nickel.

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