KR19990028577A - Shunt assembly for current measurement - Google Patents

Abstract

The shunt assembly for current measurement is made of ZTC material and consists of a substantially cylindrical shunt element 12, a pair of current connectors, and flat strips 10, 11 attached to the shunt element. Preferably, the sense connectors 13, 14 made of the same ZTC material are connected to the ends of the shunt elements and pass through the holes. The sensing connector forms part of a continuous wire through the shaft hole, which passes through the shunt element. Optionally, the sensing connector is formed with full extension of the shunt element.

Description

Shunt assembly for current measurement

The present invention relates to current measurement, and more particularly to current shunt.

A standard method of measuring current is to flow a current through a resistor of known small resistance and then measure the voltage drop across the resistor. Therefore, the current is measured by a voltage measuring device or circuit that is in fact shunted by a resistor. The shunt assembly has four terminals or connections. That is, it has two end connections through which the current to be measured passes and two other connections (usually located near the current connections) for picking off the voltage resulting from the current flowing. The latter two connections mentioned are referred to as sense or Kelvin terminals.

The connections for the sense terminals of the shunt assembly will be related to the thermoelectric effect (assuming the connector is made of a different material than the shunt assembly). The temperature of the shunt assembly is likely to change due to ambient temperature changes and the thermal effects of the current to be measured (assuming that the current is significant); Current heating as well as the thermal capacitance of the shunt will be prone to delay. To avoid temperature sensitivity, the two connectors are typically made of the same material.

In order to make an accurate current measurement, the shunt must be made at a known value. For some purposes, the value of the shunt must be precisely controlled. However, it is often sufficient to accurately measure the value of the shunt amount, and the voltage measurement is converted into a current value by proper calculation.

Shunts should also be stable. In order to achieve a moderately low resistance, the shunt is made of a metal alloy with a higher resistance than a good conductor but nevertheless does not achieve very low resistance. A very important cause of this is the instability of the shunt when the temperature changes. To overcome these, ZTC (zero temperature coefficient) alloys have been developed that have a resistance of substantially zero temperature coefficient.

The resistivity of a given material against temperature can be expressed as a polynomial function over temperature. The first term is usually dominant, and the first coefficient is the temperature coefficient of the resistance of the material, and the higher first term has a somewhat smaller coefficient very gradually over a wide temperature range. However, materials have been developed for the case where the coefficient of the first term is substantially zero. This well known alloy is called manganine and consists of 83-85% Cu, 10-13% Mn, and 4% Ni, the main term in the resistivity function being the secondary term, the resistivity being substantially constant Provide a substantial temperature range. Other materials, such as gerarin, are also useful and provide a larger temperature range where the resistivity is substantially constant. For geranine, the primary term in the resistivity function is the cubic term since both the first and second terms of the resistivity function are substantially zero.

Another requirement for accuracy is that the shunt assembly has a linear characteristic with respect to voltage versus current. When the current distribution through the shunt body tends to change slightly with the magnitude of the current, it turns out that only Ohm's law is close to the conventional shunt. This phenomenon is called "current crowding". Known methods of overcoming these effects include fabricating shunt elements in a wavy or zigzag form, and bringing many sense contacts to an average line of voltage variations due to current crowding.

In addition, the physical size of the shunt assembly adds certain requirements. In sensing large currents, it is preferred that the current connection of the shunt is very wide for a cross section on the order of several mm 2 and that the shunt assembly has a cross section of approximately the same size. It is also preferred that the shunt assembly has a length of considerable mm. Shorter lengths are difficult to control accurately and form Calvin connections, while longer lengths cause shunts that are too large.

It is a general object of the present invention to provide an improved shunt assembly.

According to the present invention there is provided a shunt assembly for current measurement, wherein the shunt assembly is generally cylindrical and includes a shunt element made of ZTC material, a pair of current connectors, and a flat strip attached to the shunt end. Characterized in that. Preferably, the sensing connector of the same ZTC material is connected to the end of the shunt element through the hole.

A particular example of the current shunt is in an electrical distribution box, in which multiple output cables are fed from multiple input cables. Typically, the box comprises a number of connectors or busbars in the form of flat strips, usually copper, and connects the input terminals to the output terminals along a curved or zig-zag routine. Current shunts with busbars allow the current through the busbars to be monitored.

Conventional shunt elements typically have portions like copper strips, which strips are coplanar. It is important to make good connections between the shunt elements to be connected and the copper strips, and this connection is usually made by electron beam welding. This places a certain minimum limit on the length of the shunt element. This places a certain minimum limit on the resistance of the shunt. In some applications, very low shunt resistance (eg in the 70 μΩ range) is desirable, but difficult to achieve in this way.

In addition, if the copper strips are oriented at right angles to each other, it is desirable to position the shunt elements at the joints in such a way that they are connected at the ends to the side edges of the other strips and extend onto one end of the strip. However, the current distribution through the shunt element is distorted, with a larger current density inside than outside. This conventional device is damaged from current crowding effects and resistance change to current.

In the present invention, of course, the strip forming the bus bar is in a plane that is offset by the length of the shunting element. This requires a crank on one of the strips if it is necessary for the two strips to return to the common plane. However, it is often desirable when the two strips are in different planes. The invention is particularly suitable in this case since it automatically introduces a change of plane between the two strips. The separation distance between these planes can be adjusted within wide limits by appropriately selecting the appropriately sized shunt elements. Also, since the end of the shunt element and the attachment of the two strips are independent, the two strips can be set at any desired angle to each other, for example in-line or at right angles.

The shunt of the present invention is easy to manufacture, inexpensive, and has high precision.

Further features of the present invention will become apparent from the following description of the shunt assembly embodying the present invention, a description of which is provided by way of example and with reference to the drawings.

1 is a perspective view of a shunt assembly.

2 is a cross-sectional view through the shunt assembly of FIG. 1.

3 is a perspective view of a modified shunt assembly.

Referring to FIG. 1, the shunt assembly consists of strip pairs 10, 11 and a ZTC shunt element 12 connected between the strips. As shown, the strips 10, 11 are in parallel planes, not separate, and the axis of the shunt element 12 is perpendicular to those planes. The angle between the two strips is shown at 90 °, but this angle obviously has any value (including 0 °, inline). For any desired shunt resistance, the distance between the two planes can be adjusted within the limits not exceeded by appropriately selecting the diameter of the shunt element. (To maintain the resistance constant, the diameter of the shunt small intestine must be increased by the square root of the path.)

The voltage across the shunt element is sensed by two sensing connection ends 13, 14. These two connection ends need to be connected to the ends of the shunt element. It is possible to form such a contact by using a disk (protruded tab) held between the end of the shunt element 12 and the strips 10 and 11. However, it is preferable to form such a contact by the connection with the center of the edge part of a shunt element. Therefore, the sensing connection end is connected to the end of the shunt element 12 through the strips 10 and 11 and through the holes 15 and 16.

It can be made of any suitable material at the sensing connection and can be attached to the end of the shunt element. However, it is preferable to insert the sensing connection end into the hole formed at the end of the shunt element. It also forms a sensing connection end of manganese (i.e., a material such as a shunt element), and forms a sensing connection end from a single length manganese wire through an axis passing through the entire length of the shunt element, as shown in FIG. It is desirable to. Some of the wires in the shunt element are actually part of the shunt element. Minimizing thermoelectric effects by using materials from sensing connections such as shunt elements.

3 is a shunt element of a modification, and is formed of a cylinder 12 'and connection ends 13', 14 'protruding from the cylinder end.

Shunt assemblies of the various components can be soldered together by applying simple soldering and heat, for example by spreading the solder fast on the appropriate area. It has been found that this produces an assembly with very stable electrical properties. The ends of the shunt elements, the opposing regions of the strip forming the busbars, the holes through the shunt elements and parts of the in-hole connectors must be soldered together. It is also found that it is not important whether the holes 15 and 16 in the strip are filled with lead or not, and that the device is very resistant to resultant property problems, for example poor lead.

It is found that such shunt assemblies typically have very stable electrical properties over a current range of 200 mA to 100 A. The diameter of the manganese rod will usually be chosen to match the current range to be measured. Very low current can be measured when the diameter is small. At the limit, the same manganese rod or wire can be used for the shunt resistor and sense connections. For very large currents, multiple loads may be used in parallel, one load may have a sense connection, or the loads may be connected together or have both sense connections with an averaged output.

The current distribution through the central part of the shunt element may be quite uniform, but the distribution through the end of the shunt element and the neighboring part of the busbar will probably have a very complex pattern. However, there is no significant current crowding or the effect of some current crowding is almost balanced.

As mentioned above, it is an object of the present invention to achieve stable characteristics rather than to be accurately determined. By cutting the shunt element to the appropriate length on a large rod of manganese, an accuracy of 1-15% can be achieved. If manganese rods are typically produced by extrusion and the diameter of the rods tends to increase as the extrusion die wears, it is desirable to measure the diameter of the manganese rods rather than using a nominal value indicating good accuracy. Do. However, when the diameter of the manganese rod is accurately controlled, much greater accuracy can be obtained, and when the diameter can be controlled for a resistance of 10 μm, it provides a resistance accuracy of about 0.1%. Deformation of lead etc. has a slight effect on accuracy.

If desired, the shunt element can be turned or grounded slowly after manufacture to adjust the diameter value of the rod. Typically, however, this value may be accurately measured and used to obtain an accurate current value from the measured voltage across the shunt element.

Claims (5)

Characterized in that it comprises a generally cylindrical shaped shunt element 12 made of ZTC material, a pair of current connectors 13 and 14, and flat shaped strips 10 and 11 attached to the ends of the shunt element. Shunt assembly for current measurement. The method of claim 1, characterized in that the current is measured by sensing a connector (13, 14) made of the same ZTC material connected to the end of the shunt element and passing through a hole in the current connector (10, 11). Assembly for current measurement. 3. An assembly for measuring current according to claim 2, wherein the sensing connector (14, 15) forms part of a continuous wire passing through the axial hole (17 in FIG. 2) through the shunt element (12). 3. An assembly for measuring current according to claim 2, wherein the sensing connector (14, 15) is formed in full extension of the shunt element (Figure 3). The novelty and inventiveness particularly described in the specification are within the spirit of clause 4H of the International Treaty (Paris Treaty).