SchulzeA,
Those are good questions and observations, let me see if I can address all of them. You are absolutely right about the stroke length, that is what I was talking about when I mentioned motion ratio. That wants to be as close to the ball joint as possible for other design considerations. The stroke length of that shock is 2 1/2 inches. As you say, that is shock stroke length, not tire travel.
Both your response and the first response of P4S concentrate on the shocks, forget about them, they are not the issue, they could be 1 or 100 inch stroke, but there is a problem if a 7 inch spring is the longest that will fit.
I also mention swaybar rating in my answer, something that P4S never mentions. I assume his calculations are without a swaybar, and THAT WILL NOT WORK either. This subject could fill another thread, but let me give this brief example more to show a concept than to be absolutely accurate. A 100lb spring and a 300lb bar gives a total rating of 400lb on that corner. A 300lb spring and a 100lb bar gives a 400lb rating on that corner. The debate over which is correct has been going on since the wheel was invented, but you must consider them together. When P4S says 400lbs on the front, that is as much as you would want to go for both combined, I do not care what the geometry looks like.
Realistically, to get this rate you need about a 250 lb spring and a 150lb bar. A 7 inch spring coil binds at 4 inches, 4 1/4 to be exact. That leaves 2 3/4 inches of spring stroke, forget the shock. Place the 530lbs guess of P4S over it and it compresses 2 1/8 inches. That leaves 5/8 of an inch for suspension travel. Put a passenger in the car and you do not have even that. If he misses that guess by even 100lbs you do not have that. If the ride height is not absolutely perfect (which it is not going to be in the real world, only on paper) you do not have that. Change the air pressure in a tire and you do not have it. For that matter, what sized tire is this based on, will everyone use the exact same tire? When the spring settles, which it is going to do, you do not have it. All of these will leave it coil bound before the suspension ever has a chance to travel. It may look good on paper, but it is not reality. Go to a 225lb spring and now any slim remote hope is gone.
There is a second way I know this. I have a junk chassis sitting here that was the R&D test bed for the development of that very shock. We got almost the entire chassis done and the prototypes sent to production before either of us realized there was a problem.
P4S,I am not trying to argue, just save the agony of another junk chassis being built, but if your numbers say it will work, go for it. At the risk of extending what has now become a debate, I have a few observations. Why change it to the shorter shock in the first place? This is the same question I asked when my problems arose. The shorter shock and smaller spring is less unsprung weight but the bigger spring that is now needed negates this, and it is much harder to make the geometry work with the short one. I do not find an upside to this change. Also on the downside, I understand you have two years of development using the Hardpoint for the longer shock, which is the first starting point of chassis design. You are going to lose every bit of your suspension analysis data. Again just my opinion but any chassis design that is changing Hardpoints after two years of development has more problems that the shock length.
