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AC circuit of inductive element

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The AC circuit in figure a below is composed of linear ideal inductive elements, and the reference directions of current and voltage are marked in the figure.

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AC circuit of inductive element

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The relationship between voltage and current

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When the current passing through the inductor is I = imsin £s t = I ¡Ô 2Sin £s T, and with it as the reference quantity, the following formula is given in the article "passive components in circuits: resistance, capacitance and inductance":

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Voltage at both ends of inductance

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The voltage at both ends of the inductance can be obtained as follows:

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Calculation formula of inductive voltage

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It can be seen from the above formula that the voltage and current on the inductance are sinusoidal quantities of the same frequency; the quantitative relationship between the voltage and current is as follows:

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The relation formula of voltage and current in inductance

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XL is called inductive reactance. When the unit of frequency is Hz and the unit of inductance is h, the unit of inductive reactance is £[.

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It can be seen from the above formula that the inductive reactance reflects the blocking capacity of the inductive element to the AC current, which is proportional to L and F. Under the same voltage, the greater L is, the greater the self induced electromotive force (EL = - L (di / DT)), the greater the resistance to the current, the smaller the current; the higher the frequency is, the greater the current change rate through the inductance, the greater the self induced electromotive force and the smaller the current. Therefore, when a coil with L inductance passes through alternating current with different frequency, its blocking effect on the current is different, that is, the value of XL is different. The higher the frequency, the larger the XL, the more difficult the current is to pass through. If f = 0, XL = 0, it means that DC current is easy to pass through inductive element. If there is inductor in DC circuit, it can be regarded as short circuit if inductor has no effect on current in steady state.

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The voltage and current waveforms in the inductive circuit are shown in Figure B above.

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The phase relationship between voltage and current is: voltage is 90 ¢X ahead of current, or current is 90 ¢X behind voltage. In the form of phasor, the relationship between voltage and current is as follows: