Verifications
LATEST: Internal Independent Pressure and Energy Pre-test, May 2022:
shows a test reaction undertaken by technicians preparing for an upcoming university test. The inventor can be heard on a mobile phone. Internal Energy Test Video, May 2022 – YouTube
Procedure:
The circuit is charged by a 240 VAC wall outlet via a power meter. i.e. the circuit capacitors are charged and then discharged during a reaction. The power meter measures the energy required to recharge the capacitors. The power meter enables us to calculate the energy required to induce a reaction in the reactor. The reactor has a pressure gauge with a peak pressure dial (red) in addition to the usual pressure gauge dial (black). The peak pressure dial allows us to calculate temperature change in the reactor during a reaction. The heat calculation is performed using online tools and shows that ‘apparently’ the reaction is producing more energy (heat) than was consumed by the circuit (to cause the reaction). i.e. 80 (joules output) / 72 (joules input) = 1.11 = 111% efficient.
In very general terms, the method employed involves conserving the energy the H2O already has (at ambient temp.), but transforming that energy to another form. The result of the transformation is the fusion of H with O (so forming Fluorine 17) and the release of energy equal to the change in mass between individual O and H atoms and single F atoms. Test results (from various test facilities) show that the F-17 does not decay via B+, but rather E.C (electron capture).
Similar tests have been conducted using D2O (heavy water) and resulted in F18.
Energy: SCITECK – UK – 18 July 2017 Revision
Test #5
Test #11
The results produced in this test seem to be different to the other four in that the pressure pulse is very high but short lived and the decay period much longer at 50ms but from a pressure level of 10psi.
As can be seen in the table above for three tests the energy generated was lower than the electrical energy input and for two of the results the energy released is higher than the electrical energy input.
The below is the second independent test and paper published by the University of Valencia in 2018 regarding Fluorine production:
Fluorine (HF): University of Valencia Report (2018) – verified Fluorine is created from the STORM REACTOR process.
The University of Valencia, led by Professor Santos Fustero, Chair of the Fluorine Symposium conducted tests in Dec. 2018, designed with the main objective of detecting the production of fluorine from the Fusion reaction happening in the STORM REACTOR®.
In conclusion, we have described an alternative method to produce HF through a simple electrical reaction between water and pressurized air. The use of deuterated water could lead to the production of fluorine-18, constituting a simple, fast and safe way to produce important fluorine isotopes in the workplace. In this sense, the STORM REACTORs® developed by Team Scotia could represent a novel and sustainable way of accessing fluorinated compounds by producing reactive fluorine species from just water.
Although the reactivity of the species in the mixture produced is still to be determined, the suspected species present are highlighted in Equation 2.
Links to published articles discussing the STORM REACTOR® Fluorine Application below:
University of Malta - 15 December 2014
Demonstrates the relationship established during a reaction between the circuit, the water, and laterally OH (Hydroxyl). In which the power of the circuit discharge is increased (versus reactions where the relationship was intentionally not established e.g. Figure 3 Log 6 below).
