Re: 50%

• To: tesla-at-pupman-dot-com
• Subject: Re: 50%
• From: GE Leyh <lod-at-pacbell-dot-net>
• Date: Tue, 31 Oct 1995 00:05:20 +0000

Tesla List wrote:


> From: "Fred W. Bach, TRIUMF Operations" <music-at-triumf.ca>

> >From hullr-at-whitlock-dot-comMon Oct 28 21:48:14 1996

> >In theory,  We should never be more than 50% efficient in energy transfer
> >from one capacitor to another!  i.e. the Cprimary to the Csecondary
> >Usually the resonator load capacitance plus Ion cloud loading.  This
> >assumes 100% coupling and zero other losses!  If fact, we are much lower
> >than that with the finest system in operation.
> >
> >50% of the capacitively stored energy always disappears in circuit loses
> >(resistive and magnetic) even with direct wired connections.  There is a
> >lot of additional wasteful garbage going on in between the primary and
> >secondary capacitors.
> >
> >Richard Hull, TCBOR
> 
>    What are you talikng about?  Some specific circuit I presume.  Your
>    post lacks quoted text and the second paragraph is rather general,
>    so I take some exception.
> 
>    For instance,
> 
>    If I take a 0.1ufd cap charged at 10KV and another identical one
>    but uncharged, and I connect them together (as you said, "direct
>    wired connections"), even with a small resisitor in series, I will
>    get a final voltage of very close to 5kV, will I not?  This is
>    nearly 50% of the energy in the first capacitor transferred to the
>    second with very little losses to the circuit.  
<snip>


Actually, No.  Richard is correct, insofar as 50% of the capacitively 
stored energy always disappears in circuit losses (resistive and magnetic) 
when _direct_wired_connections_ are used to connect the second capacitor.
The cap charged to 5kV in the above example holds only _25%_ of the initial
energy, not 50% (CV squared and and all that).
However, the 50% efficency value is by no means an upper limit, if one is
allowed to use components other than direct wires.  A switch in series with 
an inductor between the two caps will do the job quite nicely:
When the switch is closed the current starts at zero, peaks at V/ SQRT(L/C),
then returns to zero in a nice smooth haversine.  When the current crosses
zero the second time open the switch, and Voila!  Perfect energy transfer!

I guess that the message here is "Never say never."

-GL

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