- #1
christang_1023
- 27
- 3
- Homework Statement
- For the circuit shown in the figure, the inductors have no appreciable resistance and the switch has been open for a very long time.
(a) The instant after closing the switch, what is the current through the 60.0-Ω resistor?
(b) The instant after closing the switch, what is the potential difference across the 15.0-mH inductor?
(c) After the switch has been closed and left closed for a very long time, what is the potential drop across the 60.0-Ω resistor?
- Relevant Equations
- Equations have been obtained based on Kirchhoff's rule
Above is the figure of the question.
According to Kirchhoff's Rule, I have obtained three equations
$$\varepsilon-iR_{10}-L_{40}\frac{di_1}{dt}=0$$
$$L_{40}\frac{di_1}{dt}-i_2R_{60}=0$$
$$i_2R_{60}-R_{30}(i-i_1-i_2)-L_{15}\frac{d(i-i_1-i_2)}{dt}=0,$$
where ##\varepsilon## stands for emf=100V, ##i, i_1,i_2## stand for the current passing through the 10Ω resistor, the 40mH inductor and the 60Ω resistor respectively.
Although I have got equations based on Kirchhoff's rule, I am totally lost about dealing with them.
I also wonder if there is any shortcut; because an inductor and a resistor that are in series with an emf is a known model, where $$I(t)=\frac{\varepsilon}{R}(1-e^{-t/\tau}).$$