From: [email protected] 

 

can you provide links to Piantelli's patents?

 

There are two Piantelli’s with LENR IP– Francesco and Silvia, I think they are 
married, but not sure

 

WO/1995/020816 -ENERGY GENERATION AND GENERATOR BY MEANS OF ANHARMONIC 
<http://www.wipo.int/patentscope/search/en/detail.jsf?docId=WO1995020816&recNum=7&office=&queryString=FP%3A%28Piantelli%29&prevFilter=&sortOption=Pub+Date+Desc&maxRec=9>
  STIMULATED FUSION

 

WO/2010/058288 -METHOD FOR PRODUCING ENERGY AND APPARATUS 
<http://www.wipo.int/patentscope/search/en/detail.jsf?docId=WO2010058288&recNum=2&office=&queryString=FP%3A%28Piantelli%29&prevFilter=&sortOption=Pub+Date+Desc&maxRec=9>
  THEREFOR

 

The first one mentions anharmonic vibration and a temperature higher than 
Debye's temperature of the material composing the core

 

The second is a method and a generator to produce energy from nuclear reactions 
between hydrogen and a metal, comprising the steps of a) production of a 
determined quantity of micro/nanometric clusters of a transition metal, b) 
bringing hydrogen into contact with said clusters and controlling its pressure 
and speed, preferably after applying vacuum cycles of at least 10-9 bar between 
35° and 500°C for degassing the clusters; c) creating an active core for the 
reactions by heating the clusters up to a temperature that is higher than the 
Debye temperature TD of the metal, preferably a temperature close to a 
temperature at which a sliding of reticular planes occurs, in order to adsorb 
in the clusters the hydrogen as H- ions; d) triggering the reactions by a 
mechanical, thermal, ultrasonic, electric or magnetic impulse on the active 
core, causing the atoms of the metal to capture the hydrogen ions, with 
liberation of heat, preferably in the presence of a gradient of temperature on 
the active core; e)removing the heat maintaining the temperature above TD, 
preferably in the presence of a magnetic and/or electric field of predetermined 
intensity. The active core can comprise a sintered material of micro/nanometric 
clusters, or a clusters powder collected in a container, or a deposit of 
clusters onto a substrate of predetermined volume and shape, with at least 109 
clusters per square centimetre of surface, obtainable by means of methods such 
as sputtering, spraying evaporation and condensation of metal, epitaxial 
deposition, by heating up to approaching the melting point and then slow 
cooling, such methods followed by quick cooling for freezing the cluster 
structure.

 

 

 

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