In order to capture the bio potential with no tax or private subsidies, six things needed to be done.

1. Reduce the size and consumption rates of the combustor enabling energy conversion at the location of the fuel production, so as to eliminate transport problems.
2. Simplify, to allow any person to be able to operate the system.
3. Make versatile enough to accept a wide range of potential fuels primarily biowaste, so productive farm ground would not have to be taken out of production for fuel growth and individuals could offset fuel or power costs while eliminating waste and handling expenditures.

4. Make energy outputs in different forms, so as to be compatible to varying consumer system requirements.
5. Design the system so existing equipment can feed the combustor.
6. Do this all for a price that makes true business sense.

We took advantage of biowaste's insulating and bridging characteristics by combusting and collecting heat from the inside of the mass. Once contained, the mass was ignited from the inside, causing an internal combustion zone, like a cylinder of tornadic fire. Placing a heat exchanger in that internal combustion zone resulted in incredible energy output.

This bridging allowed for an extremely turbulent internal combustion zone, and the bulkiness of the mass itself acted as a refractory driving the heat inward, keeping the external container cool. Particle sizes and moisture variations had very little effect. As the fuel was insulating and radiating its own heat inwardly, it was also drying itself.

As a result a very simple mechanism was created, producing energy in four forms: heated air, heated fluids, steam and by adding existing technologies, electricity. And little auxiliary fossil fuels were required to assist combustion.

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