Version 3


    The Sham of the High Rated Current







    BY STEFAN KLEIN                                        


    1. How rated current is shown in a better light

    Coils are used in switching controllers as power coils. Parameters such as inductance, rated, saturated current and RDC, are determined and declared by the coil manufacturers in the datasheet specifications. In practice, coils of identical construction are compared in order to make a selection for a switching controller. But then the question arises for the developer, why the rated current can differ between coils of the same construction from different manufacturers.


    2. The influence of the rated current on the operating temperature























    In order to avoid any damage to the coil, consider not exceeding the specified rated current. The rated current "IR", is a result of the resistance "RDC" of the wire winding, leads to the power loss "PDCLoss".

    The DC power loss of the coil increases with the square of the current through the component and this leads to unwanted heating. Usually the self-heating of the component is included in the component's
    datasheet. The rated current is specified for a defined self-heating. For passive components this is generally a self-heating of 40 Kelvin, i.e. if the specified rated current flows through the coil, the coil heats up by 40 Kelvin. Deviations appear from manufacturer to manufacturer, because there is no worldwide standard that defines a temperature increase at which the rated current is determined.



    3. Measurement set -up to determine the rated current

    A defined test chamber is necessary, such that the measurement result is not falsified by air convection. The test chamber at Würth Elektronik eiSos, as shown in Figure 1, is along the lines of EN60512-5-2 and is made of a non heat reflecting material. EN60512 describes testing of connectors for electronic equipment. It is used as a reference, as no such definition exists for coils. A thermoelement contacts the surface of the coil using thermal paste, which enables very precise measurement of the component temperature. The measurement system is automated and the current source is controlled by software developed especially for this purpose.

    Figure 1: Measurement set-up to determine the rated current


    The rated current is determined by passing a DC current through the coil. Once the system of coil and measuring equipment has stabilised, both the temperature increase of the components, as well as the
    ambient temperature, are measured using sensors. If the temperature increase is less than 40 K, the current passed is increased stepwise until heating of 40 K is attained. Once the self-heating of 40 K is attained, the current passed through the coil is read off and declared as the rated current.


    4. Influences on the measurement

    Even within the test chamber there are influences that can significantly falsify the measurement result. During measurement, the coil's connection to the current source is critical, as unwanted heat dissipation produces falsification of the measurement results. For this reason, care is taken at Würth Elektronik eiSos that the component's heat coupling to the environment during measurement is as low as possible. Figure 2 shows a reference measurement with various contacting options for a coil.

    Figure 2: Comparison of contacting options


    For this reference measurement the Würth Elektronik eiSos WE-LHMI series coil 744373460082 in the 7030 package is used and a current of 9 A is passed. The type of contacting significantly influences the
    measurement result. The greater the mass of the contacts, the more heat can be dissipated from the contacts and the lower the relative temperature change of the coil. The first example from the reference measurement shows, for example, that a WE-LHMI with 7030 package only heats up by 30.9 K if the coil is connected by soldering the wires and is contacted via large clamps. With smaller clamps at the same current, the temperature rises by 35.8 K. This type of contacting is not practical, however. In its datasheets, Würth Elektronik eiSos recommends a pad design for each coil, which serves as the basis for such measurements. In order to reflect the standard during measurement, FR4 of 1.5 mm thickness is used as the substrate material and 35 μm copper, chemically gold plated. The rated current is
    measured using the four-pole method so the resistance of the connection to the power supply is kept as low as possible. This also avoids high heating of the measurement cables.


    Figure 2 shows the third contacting option as a circuit board, which is used as an example with the coil from the WE-LHMI product family and 7030 package. At a current of 9 A the coil heats up by 40 K.
    This reference measurement shows that the temperature difference can be up to 9.1 K. Generally, many coil manufacturers make no statements about the contacting method, so their measurement method cannot be reproduced. However, if two coils of identical construction from different manufacturers are measured with the same measurement and contacting method, the same results should be obtained.


    5. Comparison of coils

    In the following, a Würth Elektronik eiSos coil from the WE-LHMI product family is compared with an coil of similar construction from a competitor. Both coils are made of round wire and are pressed in a core
    made of an iron powder mixture. The properties are compared in the table.

    Interestingly, the rated current differs by 4 A between the two coils. Theoretically, there can be no difference given the same package and same RDC. As an experiment, the rated current of both coils was measured and compared using the Würth Elektronik eiSos measurement set-up. For both measurements, the same measurement set-up, the same contacting method and the same measurement board were used. Figure 3 shows the characteristic curve of the reference coil (in blue) is almost identical to the characteristic curve of the WE-LHMI 744373460082 (red dashed line).


    Figure 3: Characteristic curves of the rated currents of both coils



    Figure 4 shows the temperature of both coils measured with a thermal imaging camera. The temperature of the left coil, WE-LHMI, at a rated current of 9 A minus the room temperature is 40.1 C. Higher rated
    currents can be achieved with Würth Elektronik eiSos coils from the WE-MAPI product family.


    Figure 4: Thermal images of both coils



    On the right of Figure 4 the temperature of the other coil at the same rated current minus the room temperature is shown. It is 40.7 C°. The difference between the two temperature measurements is just 0.6 K and is attributed to component tolerances. Both characteristic curves show self-heating of 40 K at a rated current of 9 A. In addition, the two coils of the same package type have the same resistance value of 6.7 mΩ. As a result, both coils have the same power loss "PDCLoss":

    This fact implies that the rated current of the other component is determined with a measurement method with which there must be a high level of heat dissipation. The low deviations in the characteristic curve are caused by component tolerances. They occur even when comparing coils of the same construction originating from the same series from the same manufacturer.


    6. Interpretation of results

    The investigation of the rated current by measurement reveals that the rated current is dependent on external influences during the measurement. High heat removal can falsify the measurement result and lead to inexplicably high rated currents. If coils from Würth Elektronik eiSos are compared with other coils, attention should be placed on the package design and where RDC is identical. Assumption is that the rated current is determined at the same self-heating. If the package design and RDC are the same, the rated current of both coils is the same.



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    Würth Elektronik eiSos GmbH & Co. KG

    Max-Eyth-Str.1, 74638 Waldenburg, Germany

    Tel.: +49 (0) 7942 / 945 – 0