Ok, bit of a further reply, I thought it would be worth posting here as it does illustrate why we need ALL the information rather than snippets because it can change the question completely.
Basically the idea is to discharge a capacitor with 945V stored via an inductor.
In this case – pictured here
View attachment 61188
It is not a simple constant voltage step change, the capacitor will have a store of energy, as the switch is closed it will discharge into the coil, this would produce a back emf – this interaction between the decay of voltage from the capacitor and growth of current through the inductor “fight against each other” – a bit like dropping a weight on a spring – the weight will fall then the spring will pull it back, then the weight will fall etc – basically discharging a capacitor into an inductor will oscillate!
Rather than just L di/dt the equation becomes:
View attachment 61190
Which is a second order differential equation – hence the oscillation.
There are a number of shortcuts to solving this, depending on the relative values of C, L & R – as here:
View attachment 61189
So forcing a low resistance will cause a decaying oscillation, but increasing the resistance beyond 2 Sqrt (L/C) will cause a non-oscillatory decay!
If I was solving this for the generic solution, I would use laplace transforms to solve the differential equation as a set of linear equations, I may do this later if the football is rubbish!
Probably the easiest solution these days is to download a program such as LTSpice – it’s free and allows time domain modelling of any circuit – not just L & C, but actually any SCR you may wish to use as the switching device.
This requires little mathematical knowledge.
