DE20112486U1 - Low-resistance measuring resistor - Google Patents

Description

Description

Low-ohm measuring resistor

The invention relates to low-resistance measuring resistors with two separate connection elements, a resistance element and connection parts made of an electrically conductive material.

Measuring resistors of known design consist of a wire or sheet-shaped resistance material.

In a first variant, the taps for measuring the voltage drop across the electrical resistance are attached to the electrical resistance by means of a material change, e.g. soldering or welding. This leads to the formation of transition materials in the connection point, the resistance value of which changes non-linearly over a longer period of time and with temperature fluctuations. This leads to errors in the measurement of this voltage drop, which are accompanied by errors in the further evaluation of these measurement results. In other solutions, the taps are located in front of the connections between the measuring resistor and its connection point with the electrical conductors supplying or discharging current. Temperature fluctuations depending on the flowing electrical current and the associated changes in resistance lead to errors in the determination of the voltage drop across the measuring resistor. These errors are then based on the non-linearity of such resistors.

The electrical current flow of sheet-shaped measuring resistors is limited by the amount of heat to be dissipated.

When a wire-shaped resistance material is wound on a tubular carrier, an additional inductive component is created, so that a non-linear resistance is present.

The invention specified in claim 1 is based on the problem of sharpening a largely ohmic measuring resistor for measuring electrical currents.

This problem is solved with the features listed in claim 1.

A U-shaped design of a resistance body as a low-resistance measuring resistor has the particular advantage that the direction of the flowing electrical current in the legs is opposite. This means that the magnetic flux resulting from the flow of electrical current is also opposite, so that there is compensation for the magnetic fields of the legs through which current flows. The resulting influences on a downstream electrical circuit arrangement are avoided, so that resulting errors are suppressed. A magnetic field that could cause errors only occurs around the curved part of the U-shaped low-resistance measuring resistor. This arrangement also advantageously means that external fields cannot introduce incorrect voltages via external induction. Positive connections between the connection elements and the resistance element of the low-resistance measuring resistor are advantageously designed as press connections. This ensures that there are as little material changes in the connection points as possible and as little non-linearities in the measuring resistor as possible. There is a linear relationship between the flowing electrical current and the equivalent voltage drop that can be measured between the connecting parts. Another advantage of such a connection is that there are largely no material changes in the connection points, even over a long period of time. This means that consistent measurement results are achieved over a long period of time. Material-bonded connections are advantageously made as welded connections using electron beam welding. When using this process, which takes place under vacuum, no additives are required to protect the weld seam from atmospheric oxygen. Structural transformations with such substances or atmospheric oxygen are thus largely avoided.

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The connection parts as potential connections are arranged directly in or on the resistance element of the measuring resistor and are located between the connection elements in or on the resistance element. The connection points of the resistance element with the connection elements including the current-carrying conductors are therefore located outside the connection points of these components of the low-resistance measuring resistor. This fact in turn largely avoids the non-linearities caused by this.

Strip-shaped connecting parts are made primarily from foils or sheets. This ensures consistent material conditions across the volume of the connecting part.

Advantageous embodiments of the invention are set out in claims 2 to 13.

According to the development of claim 2, favorable designs for the resistance element of the measuring resistor are a plate or a body with a cross section of either a conic section, in particular a circle or ellipse, or a polygon. A plate is particularly suitable for applications with lower electrical currents up to about 20 A and a body is particularly suitable for applications with higher electrical currents up to about 60 A. A cylinder as a body with the cross section of a conic section is advantageously suitable for a positive connection with the connection elements. For this purpose, a hole must be made in the connection element. A plate, on the other hand, is advantageously suitable for a material connection.

The low-impedance measuring resistor according to the development of claim 3 is particularly suitable for measuring large flowing electrical currents. For this purpose, two connection elements are preferably arranged next to one another, which are bridged via a U-shaped resistance element.

This type of structure results in a component with a small width and depth. This low-resistance measuring resistor is therefore particularly suitable as a multiple resistor for use in multi-phase networks.
The connecting elements are preferably designed as cuboids, whereby the geometric

Dimensions can be implemented depending on the electrical currents to be measured. Electrical cables of corresponding cross-sections can be easily contacted with the cuboids as connection elements using known detachable connection techniques.

A resistance element with a circular or predominantly circular cross-section according to the development of claim 4 results in a relatively large surface area, so that a small electrical resistance can be achieved. Heating, especially with large electrical currents, is minimized. Furthermore, such a cross-section offers the advantage that there is a large contact surface between the connection elements and the resistance element, in particular the pressed-in resistance element. The contact surface can easily be predetermined by the length of the legs of the resistance element and the depth of the openings in the connection elements that accommodate the resistance element. A large contact surface ensures a low electrical resistance between the connection elements and the resistance element.

With positive connections, material transformations in the connection points are largely avoided.

The further development of claim 5 leads to a press fit between the connection elements and the resistance element. This ensures both a firm connection of the elements and a low electrical resistance between the elements.

A greater hardness of the material of the connection element compared to that of the resistance element according to the development of claim 6 leads to the softer material flowing around the harder material over a longer period of time. Geometric changes caused by this, which are associated with changes in the electrical resistance, are largely avoided. Measurement errors resulting from these changes are thus largely avoided.

The realization of the connection element according to the development of claim 7 as a body with an L-shaped cross-section offers the further advantage that the horizontal leg can be used as a connecting part of the current-carrying conductors.

A wide variety of connection variants can be implemented by using a spring or screw arrangement. Economical variants are provided by using a clamp in conjunction with a screw connection or a clamp connection acting via a spring. A further advantage is that the vertically arranged surface of the connection element can also be used as a stop for the current-carrying conductors.

The resistance element can be advantageously calibrated via an opening in the resistance element according to the development of claim 8. The geometric dimensions of the opening determine the size of the electrical resistance of the resistance element and thus of the low-ohmic measuring resistance. The opening is advantageously drilled.

Fastening by subsequent plastic deformation of openings in the resistance element after the placement of the end areas of the wire or strip-shaped connecting part according to the development of claim 9 means that the use of additional materials or material transformations in the connection points and the non-linearities of the resistance characteristics caused thereby are largely avoided. A particularly firm hold is achieved when fastening strip-shaped connecting parts in round openings.

The openings in the resistance element are advantageously drilled or punched.

The end areas of the wire or strip-shaped connecting parts are advantageously welded to the resistance element according to the development of claim 10. In particular, welding processes can be used in which a firm connection is achieved without additional materials. Such welding processes include electrical spot welding, ultrasonic welding, laser beam welding or electron beam welding. This minimizes non-linearities in the resistance behavior of the low-ohm measuring resistor.

Identical materials for the resistance element and the connection parts according to the development of claim 11 ensure a low electrical resistance between the resistance element and the connection parts, especially over a long period of time.

Material transformations due to the thermal influences of the flowing electrical current in the resistance element are thus largely avoided.

The realization of the tubular connections preferably in copper guarantees an easy and known contact of the low-ohm measuring resistor from the outside.

Several low-resistance measuring resistors according to the invention are particularly suitable for use in multi-phase networks. An arrangement of the low-resistance measuring resistors next to one another according to the development of claim 12, wherein the legs of the U-shaped resistance elements lie in one plane, is a space-saving variant for use in multi-phase networks.

Casting several low-resistance measuring resistors according to the development of claim 13 results in a compact component that is easy to handle. Handling here means in particular transport, storage and installation in a device.

Embodiments of the invention are shown in the drawings and are described in more detail below.

Show it:

Fig. 1 a low-resistance measuring resistor with at least one plate-shaped resistance element,

Fig. 2 a low-resistance measuring resistor with a U-shaped resistance element with a circular cross-section in a front and a side view and

Fig. 3 shows a schematic diagram of a low-ohm measuring resistor for use in a three-phase network.

1. Example

A low-resistance measuring resistor with a U-shaped resistance body consists in a first embodiment of a resistance element 1, two connection elements 2 and two connection parts 3 (shown in Fig. 1). The resistance element

and the connection elements 2 are plate-shaped parts that are connected to one another in such a way that a U-shape is created (Fig. 1). The low-resistance measuring resistor designed in this way is particularly suitable for measuring small electrical currents of up to around 20 A. The plate-shaped parts that form the legs of the U-shape are the connection elements 2, with which the low-resistance measuring resistor can be connected in an electrically conductive and detachable manner to the electrical network on the one hand and to the electrical consumer on the other. These are made of tinned copper. The plate-shaped part that forms the middle part of the U-shape is the resistance element 1 as the actual low-resistance measuring resistor. This is made of a copper alloy. The plate-shaped parts are attached via electron beam welded connections. One end region of the connection parts 3 as potential connections is attached to the resistance element 1. These are wire or strip-shaped. In one embodiment, the resistance element 1 has a hole as an opening, whereby manual or mechanical handling is not significantly reduced. A small electrical resistance leads to smaller losses in the form of heat. A further advantage of the opening is the associated possibility of calibrating the low-ohm measuring resistor via the geometric dimensions of the opening. The connection parts 3 as potential connections are located near the opening.

2. Example

In a second embodiment, a low-resistance measuring resistor consists of two connection elements 2 made of a material with high electrical conductivity, a resistance element 1 made of a material with an electrical resistance and two connection parts 3 (shown in Fig. 1). A low-resistance measuring resistor realized in this way is particularly suitable for measuring large flowing electrical currents. A connection element 2 is a body with an L-shaped cross-section. The horizontal part represents part of a clamp connection for the power connection. The clamp connection is realized by a terminal 4 with a screw or a spring as a clamp element. In Fig. 2, this is only shown by the arrow, since such an arrangement is generally known. The other part of the connection element 2 is a cuboid. The surface facing the horizontal part is also the stop for the power connection. Two connection elements 2 designed in this way are arranged next to one another and connected via a

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Resistance element 1 is connected to one another. The resistance element 1 is U-shaped and has a circular cross-section. It is inserted into the cuboids of the connection elements 2 in such a way that the horizontal part and one leg form a right angle. The end areas of the legs of the U-shaped resistance element 1 are fastened to the connection elements 2 via positive connections caused by elastic deformation. For this purpose, one of the connection partners is designed to be undersized or oversized so that a press fit is present.

In a first embodiment, two drilled or punched openings are made in the resistance element 1 at a distance from one another. An end region of a wire- or strip-shaped connection part 3 is placed in each of the openings. The connection parts 3 are fastened in the resistance element 1 by subsequent plastic deformation. In a second embodiment, an end region of the wire- or strip-shaped connection parts 3 is fastened as potential connections on the resistance element 1 at a distance from one another.

The resistance element 1 and the connection parts 3 are made of the same material. Such a low-resistance measuring resistor is used for single-phase networks. In multi-phase networks, low-resistance measuring resistors are used according to the number of phases. These are advantageously positioned so that the horizontal parts of the connection elements 2 are arranged parallel to one another and point in one direction. The low-resistance measuring resistors are cast into a component 5. Fig. 3 shows such a component 5 for use in a three-phase network.

Claims (13)

1. Low-resistance measuring resistor with two separate connection elements, a resistance element and connection parts made of an electrically conductive material, characterized in that the resistance element ( 1 ) is a U-shaped resistance body, that the two connection elements ( 2 ) of the measuring resistor and the resistance element ( 1 ) are electrically conductively connected to one another via positive and/or material-locking connections and that an end region of two wire- or strip-shaped connection parts ( 3 ) are fastened at a distance from one another either in or on the resistance element ( 1 ). 2. Low-resistance measuring resistor according to protection claim 1, characterized in that the resistance element ( 1 ) of the measuring resistor is a plate, a body with the cross section of a conic section or a body with a polygonal cross section. 3. Low-resistance measuring resistor according to protection claim 1, characterized in that the end regions of the resistance element ( 1 ) are connected to the connection elements ( 2 ) by form-fitting connections caused by elastic deformations and that an end region of two wire- or strip-shaped connection parts ( 3 ) are connected at a distance from one another either in or on the resistance element ( 1 ) in such a way that elements are present which are free of thermo-stress with respect to one another. 4. Low-resistance measuring resistor according to claims 1 to 3, characterized in that the resistance element ( 1 ) has a circular or predominantly circular cross-section. 5. Low-resistance measuring resistor according to protection claim 4, characterized in that the cross section of the connection element ( 2 ) in the region of the connection between the connection element ( 2 ) and the resistance element ( 1 ) is larger in all dimensions than that of the resistance element ( 1 ). 6. Low-resistance measuring resistor according to protection claim 5, characterized in that the material of the connection element ( 2 ) has a greater hardness than that of the resistance element ( 1 ). 7. Low-resistance measuring resistor according to protection claim 1, characterized in that the connection element ( 2 ) is a body with an L-shaped cross section, that the horizontal part is a first part of a clamp connection of the power connection and that the vertical part is a receptacle of the end region of the resistance element ( 1 ) and stop of the power connection. 8. Low-resistance measuring resistor according to claim 1, characterized in that the plate-shaped resistance element ( 1 ) has an opening serving for calibration. 9. Low-resistance measuring resistor according to protection claim 1, characterized in that an opening is made at a distance in the resistance element ( 1 ) and that an end region of the wire- or strip-shaped connection part ( 3 ) fastened by a subsequent plastic deformation is arranged in the opening. 10. Low-resistance measuring resistor according to claim 1, characterized in that a wire- or band-shaped connecting part ( 3 ) is welded to the resistance element ( 1 ) at a distance. 11. Low-resistance measuring resistor according to protection claim 1, characterized in that the resistance element ( 1 ) and the connection parts ( 3 ) consist of the same material. 12. Low-resistance measuring resistor according to claim 1, characterized in that several low-resistance measuring resistors are arranged next to one another. 13. Low-resistance measuring resistor according to protection claim 12, characterized in that the low-resistance measuring resistors are components of a cast component ( 5 ) or are themselves a component.