dr dodge said:
Last night i discovered the one of first hot air engines (buckett) used valves.
dr
Another invention-suggestion: The Stoddard-engine
http://en.wikipedia.org/wiki/Stoddard_engine
I, personally, refer to The Stoddard Engine at the original hot-air-engine, maybe I'm wrong. It is in principle a valved two-lane "Stirling", or an "all-vapor Rankine", if you will.
For your use, I suggest setup with parallel-array-garden-hoses cooled underground or rather in running water if available (low pressure-section). Then the cooled air enters high pressure/low capasitity-piston-compressor. Air now holding elevated Temp. from compression, receives your T-in from sun (must of course be higher than compression-derived T of medium). Expantion then runs a larger displacement piston cylinder( or same size at higher rev.) towards low pressure, and cooling as described above.
Compressor may be valved with one-way-valves, like a normal air compressor, while engine must be valved like a air/steam engine, in principle. Compressors and air-motors are shelf-products, yet the air-motor must handle temperatures higher than normal in garage.
In short: Pressureelevation determined by compressor-capability or T-in, combined with good cooling, determines theoretic max-thermal eff. (DeltaT/Absolute T1) It improves efficieny further to heat expansion-cylinder with T1 , and cool compression cylinder with T2, like in a Stirling. To approach Carnot-cycle (and avoid flaws of Stirling) you would also need adiabatic compression and expansion on final stage of each, suggesting at least 2 cylinders for each action whereof the first stage isobaric, and final stages temperature-isolated.
This machine is in my opinion closer to Ideal Carnot Cycle than the Stirling, because I find that the Stirling has serious flaws to the Carnot-cycle during gas transmission. Recuperator would have no effect, if the machine was perfect. Recuperators only works because pressure and temperature are at faulted values between actions. The religious item recuperator (which really is a half-effective crossflow heat-exchanger), reverses some of the uncalledfor effect (which is heating at low pressure, cooling at high pressure). In this aspect the Stoddard is better, as it performs not the same counteractive actions (providing adiabatic stages present). But it has valves (causes friction and entropy-increase) and therefore relies on good compressor/motor-mechanical efficiency (low friction)to work. That was difficult in 1933, but perhaps possible now.
I suggest to check (research, test) mechanical efficiencies on hardware you chose, to know what total mechanic loss you will encounter. Since Stoddard is loopish, no strangling of lines are necessary to avoid dead-water, as in Stirling, losses elsewhere can remain low.
Steam: It is conceivable to replace air with saturated steam (continuosly vaporized), complicating the system and reducing possible T1, yet solving lubrication and sealing-issues. present with air at high pressure/temperature. (Train-steam-engines used no oil in motors). Condensate formed can be picked up from low point at condenser and sucked into compressor with injector.
Oil for lubrication is also possible, but limits T1 to oilburn-temp. as mentioned by CFDFEAGURU. Might help to separate oil (cyclone?) after compressor and introduce it to engine after sunheat-collector, thereby avoiding partially very high temp-exposure between sun and oil.
Material-problems reducing possible T1-p1 was, and is, the main problem to reaching high Carnot-eff. in heat-engines
Best of luck with important work.
