NEC model of an 80/40 dipole using bootstrap coax traps
I have constructed an NEC model of an 80/40 dipole using bootstrap coax
traps. I have generated a helix of GW elements for the RG58C/U coax coil,
and use NT cards to model the coax interior.
Plain conductors are loaded with copper conductivity.
I am grappling with approprate conductivity for the outer surface of the
coax coil, thinking that it must be greater than copper because of
proximity effects and braid effects. I have initially tried loading those
segments with conductivity of one tenth of copper... but I don't expect
that will make the RF resistance tenfold.
With those numbers, the loss in the interior of the coax is more than
half the total loss.
Has anyone experience or thoughts on an appropriate way to load the
conductor representing the outer surface of the coax coil forming the
trap?
The model is below for anyone wanting to play with it. NOTE: the NT cards
are appropriate only at 7.05MHz. Some wrapped lines will need fixing.
Owen
CM 80/40m trapped dipole using coax traps
CM Alternative to NT cards:
CM TL 24 1 101 1 50 2.4 0 0 0 0
CM TL 14 1 103 1 50 2.4 0 0 0 0
CE
GH 1 80 0.005 0.05 0.0275 0.0275 0.0275 0.0275
0.00165
GW 2 1 0.0275 0 0 0 0 0 0.00165
GW 3 1 0.0275 0 0.05 0 0 0.05 0.00165
GW 4 1 0 0 0 0 0 0.05 0.00165
GM 10 0 0 90 0 8 0 10 1
GM 10 1 0 180 0 0 0 20 11
GW 101 20 -8.05 0 10 -14.5 0 10 0.001
GW 102 31 -8 0 10 8 0 10 0.001
GW 103 20 8.05 0 10 14.5 0 10 0.001
GE -1
LD 5 0 0 0 58000000
LD 5 0 1 80 6444444.4
LD 5 0 84 163 6444444.4
GN 2 0 0 0 13 0.005
EK
EX 0 102 16 1 0
NT 24 1 101 1 1.992e-3 -5.340e-2 -1.983e-3 5.701e-
2 1.992e-3 -5.340e-2
NT 14 1 103 1 1.992e-3 -5.340e-2 -1.983e-3 5.701e-
2 1.992e-3 -5.340e-2
FR 0 0 0 0 7.05 0
EN
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