My general thought is that with properly working components, if you can't keep it at 160* with a 160* t-stat, you won't keep it at 195* either. The cooling system is inadequate.
I've had vehicles that couldn't be overheated...the temp was rock solid regardless of load or ambient temps.
In some cases there might be an equilibrium reached as the temperature difference between ambient and coolant temp gets so large that the radiator becomes efficient enough to control the heat generated, but I doubt it. Normally the problem is a vicious cycle, that once started, cannot be stopped except to lower the load. As you note the air inlet on the trucks is relatively small. GM's solution seems to have been adding capacity...even on the later trucks they didn't change the dimensions of the core support cutouts, but if there was an additional load, coolant capacity was increased. I'm sure that some of the additional core space contributed to cooling, but it can't be anywhere near as efficient to the section of the radiator core exposed to straight through airflow. Wish I could find a photo of those that really made it apparent, this is as close as I can get: http://s18.postimg.org/9l5xeid89/engine_bay_3.png The furthest hole towards the driver fender (past the last bolt, you can see the threads in it) is the outermost bolt for the "big" radiator. That is far beyond the cutout in the core support.
I think it would be interesting to use a coolant reservoir of a gallon or so to see if that would change things in vehicles that have problems with heat under certain conditions. I measured the coolant capacity of a radiator for an 80's Corvette, as I recall it was 1.5G, which IMO is not much capacity.
I've had vehicles that couldn't be overheated...the temp was rock solid regardless of load or ambient temps.
In some cases there might be an equilibrium reached as the temperature difference between ambient and coolant temp gets so large that the radiator becomes efficient enough to control the heat generated, but I doubt it. Normally the problem is a vicious cycle, that once started, cannot be stopped except to lower the load. As you note the air inlet on the trucks is relatively small. GM's solution seems to have been adding capacity...even on the later trucks they didn't change the dimensions of the core support cutouts, but if there was an additional load, coolant capacity was increased. I'm sure that some of the additional core space contributed to cooling, but it can't be anywhere near as efficient to the section of the radiator core exposed to straight through airflow. Wish I could find a photo of those that really made it apparent, this is as close as I can get: http://s18.postimg.org/9l5xeid89/engine_bay_3.png The furthest hole towards the driver fender (past the last bolt, you can see the threads in it) is the outermost bolt for the "big" radiator. That is far beyond the cutout in the core support.
I think it would be interesting to use a coolant reservoir of a gallon or so to see if that would change things in vehicles that have problems with heat under certain conditions. I measured the coolant capacity of a radiator for an 80's Corvette, as I recall it was 1.5G, which IMO is not much capacity.
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