Overunity Electrical Devices Are Permissible By The Laws of Physics

Overunity Electrical Devices Are Permissible By The Laws of Physics
The overunity electrical energy system is permissible by the laws of physics and is not in
any manner perpetual motion. It simply extracts excess EM energy from an ubiquitous
source, through a dipole as a receiver, and collects that excess energy, conducts it to the
load, and separately dissipates it in the load to power the load, without using any of the
collected energy to perform work inside the source to dissipate the source-antenna. It is
directly analogous to a heat pump, which is well-known to perform at overunity
operational efficiency under nominal conditions.
In Conclusion
Primarily my associates and I believe we have corrected an ubiquitous error made in
present power systems that prevents these systems from realizing their already-inherent
overunity operational efficiency. We also firmly believe that the permissible electrical
overunity device is an idea whose time has finally come.
Notes and References
1. T. E. Bearden, "The Final Secret of Free Energy," distributed over the Internet, Feb.
9, 1993. The paper was also published in Magnets, 7(5), pp. 4-26 (1993); in
Explore!, 4(3/4), pp. 112-126 (1993), and in several other media.
2. For proof that you can charge an ordinary capacitor almost without entropy, see I.
Fundaun, C. Reese, and H. H. Soonpaa, "Charging a Capacitor," American Journal
of Physics, 60(11), pp. 1047-1048 (1992). A capacitor can be step-charged in small
steps to dramatically reduce the entropy required to charge it. In the limit, a
theoretically perfect capacitor can be fully charged without any electrical current or
work at all, i.e., you can simply transport the excess energy density (the potential
gradient) of the open circuit voltage of the source to the collector, and couple that
to the electrons trapped in the capacitor plates, without electric current from or
through the source.
3. M. G. Calkin and D. Kiang, "Entropy Change and Reversibility," American Journal
of Physics, 51(1), pp. 78-79 (1983).
4. F. Heinrich, "Entropy Change When Charging a Capacitor: A Demonstration
Experiment," American Journal of Physics,54(8), pp. 742-744 (1986).
5. V. K. Gupta, Gauri Shanker, and N.K. Sharma, "Reversibility and Step Processes:
An Experiment for the Undergraduate Laboratory," American Journal of Physics,
52(10), pp. 945-947 (1984).