Maybe Lorentz forces from oscillating magnetic field keeps everything stirred up
http://en.m.wikipedia.org/wiki/Lorentz_force On Saturday, October 11, 2014, Axil Axil <[email protected]> wrote: > Hydrogen movement is a old trick in nuclear reactors > > > http://en.wikipedia.org/wiki/Hydrogen-moderated_self-regulating_nuclear_power_module > > As the temperature goes up, the hydrogen goes away from the site of the > reaction. The question for us is how Rossi has engineer passive > temperature based failsafe control into his reactor by moving hydrogen > around inside his reactor. > > Or did he do it through luck....Or has he done it at all... > > On Sat, Oct 11, 2014 at 2:55 PM, Axil Axil <[email protected] > <javascript:_e(%7B%7D,'cvml','[email protected]');>> wrote: > >> Another advantage that this conjecture might imply is that the nickel >> particles will suffer far less isotopic transmutation damage from the >> gaseous hydrogen if the particles were poisons by air. >> >> Is Rossi this clever or are we overestimating his genius? >> >> On Sat, Oct 11, 2014 at 2:47 PM, Jack Cole <[email protected] >> <javascript:_e(%7B%7D,'cvml','[email protected]');>> wrote: >> >>> This is something I've wondered about with the E-Cat. Has anyone ever >>> seen Rossi vacuum the air out of a chamber before adding hydrogen? I can't >>> recall a single instance--suggesting he leaves the air in. It's an >>> interesting conjecture that the air may actually serve a purpose of putting >>> the brakes on the reaction. >>> >>> On Sat, Oct 11, 2014 at 1:21 PM, Axil Axil <[email protected] >>> <javascript:_e(%7B%7D,'cvml','[email protected]');>> wrote: >>> >>>> Air poisoning of the reaction has been an iron clad rule in Ni/H >>>> technology from its beginning. Now Rossi has overcome this poisoning no no. >>>> >>>> >>>> >>>> One way that this might happen is that the reaction no longer occurs in >>>> the gas phase where the nitrogen in the air and hydrogen can mix. The >>>> hydrogen might become chemically bound to any number of elements like >>>> lithium and/or carbon after it is released from the lithium aluminum >>>> hydride storage medium leaving the nitrogen floating above it all far from >>>> the reaction site. >>>> >>>> >>>> >>>> The reaction might be occurring in solid form with hydrogen bound to >>>> some other combination of elements. Lithium seems the most likely chemical >>>> mate for the hydrogen solid state storage system because of the high >>>> temperatures needed to release the hydrogen from the lithium. >>>> >>>> >>>> >>>> This implies that the reaction occurs in two parts. The nickel powder >>>> produces an EMF beam that reaches out from beyond the nickel particle and >>>> affects the hydride at some considerable distance from the nickel particle. >>>> >>>> >>>> >>>> When the hydrogen is in gaseous form, the nitrogen poisons it. However >>>> when the hydrogen becomes chemically bound in a hydride, it can participate >>>> in the reaction. >>>> >>>> >>>> >>>> This is a great burnout control technique because temperature rises >>>> will reduce the intensity of the hydrogen reaction in the solid state. >>>> This gas poisoning in the gaseous state puts a ceiling on how high >>>> the temperature of the reactor can go. >>>> >>> >>> >> >
