so, another couple of caveats...
I've done this initial 'napkin analysis' at 60mph; which I think should be fine for right now... it'll mostly mean that the 'raw downforce (in pounds)' values will look "low". The main reason I'm providing them, is they help to show how I'm attempting to balance the aero load on the car.
I managed to find some basic numbers on the P1800, including 'Ax' cross-sectional area, and drag coefficient. I reckon both of these are low, compared to your car... but it's a start. I've also given a 'book-end' of 'low front downforce' and 'high front downforce' based on cross-sectional area; specifically 0.25 and 0.4; which works out to ~43#s and ~70#s of downforce.
plugging all those assumptions (orange cells)... plus some values from ToW... into some equations/cells (blue cells)... we get the following:
so... !yay!... numbers! but, what's it all mean!?
There's two main 'beneficial' take-aways from the wing you've designed:
1) The 24" chord means that even at a lowly 60mph, you're wing is up into the "normal Reynold's Number (Re)" regime.
2) The N63-412 in that wing (based on my assumptions), should be able to balance out the most front downforce I'd expect you to generate; but probably not much more.
Those two benefits, though, are weighed down by a whole bunch of detriments:
1) The 54"x24" wing means it has a planform AspectRatio (AR) of just over '2' (2.25)... it's hard to tell how effective your pedestal mounts will be as 'end plates', so I've estimated them as having an 'aerodynamic effective height' of 8inches, which helps to bump the effective AR to 2.88. Most of the time, anything under '5' is "low"... and anything under '3' is usually powered by a jet engine, or strapped to an F1 car.
2) The Low AR means the wing will struggle to make downforce, and it will have more drag that you'd like.
3) Despite an apparent 'excess' of area, even at the "Low Front Downforce" balance setting... the rear wing would need to be around 3deg and making a Cl of 0.7... which actually pushes the N63-412 'on the edge' to 'outside' of it's Laminar Drag Bucket... so you wouldn't particularly be benefiting from the foil's "claim to fame".
4) This is more a caveat. But the drag coefficient I've included here is based on the 'wind tunnel test data' provided in Theory of Wing Sections, at 3e6 Re (about 3x what your wing would see); and I'm using the "perfectly clean test article" drag coefficient, not the 'standard roughness' coefficients... so the drag shown is probably a bit "optimistic" (i.e. low). That's not a big deal now... but it's worth bearing in mind as I add more in.
I should have probably mentioned this elsewhere... but I think you have the wing mounted too low... and it'll block your rearward vision in "an annoying way"... while also creating an in-flow angle of attack (AoA) which might make it difficult to get the wing set right to balance the front.
Alright, TL;DR / Summary:
I think the chord of your wing is too big.
I don't think the N63-412 foil is a good match for what you're doing. It's fairly limited in camber, and the laminar drag bucket reduction falls outside of where you'd most likely end up attempting to use the wing/foil.
I think those are the main take-aways, from a 'napkin analysis' of that wing. Next, I'll see about what a "quick, dirty, and cheap" alternative would look like / compare.
