Off the top of my head, Godes needs to do a few more things as follows:
Use nickel micro-powder to get a big increase in reaction surface area. Use SWNTs because they are one dimensional superconductors with virtually no low heat production and very high current carrying capability. Use a high pressure hydrogen envelope to maximize proton packing and hydrogen ionization. Cheers: Axil On Fri, Jul 13, 2012 at 8:50 PM, Chemical Engineer <[email protected]>wrote: > Godes is using the pulsed microwire current in his "wet" boiler design > with an approx 2:1 gain. He will have the same challenge as everyone else > to convert to a "dry" boiler design using a powder/gas system and achieve > higher gains. > > > On Friday, July 13, 2012, Axil Axil wrote: > >> Robert Godes of Brillouin Energy does not use a laser. Do not be >> confused. I only used the laser description as an example of the priciple >> of cold pulsing. >> >> >> http://www.google.com/patents?id=nWbjAQAAEBAJ&pg=PA1&lpg=PA1&dq=Brillouin+Energy&source=bl&ots=LKEzTpOozE&sig=5xdDLBzm19a6ExkrCMeiS4bxL7o&hl=en&sa=X&ei=EbQAUOboO8L10gGI0ZC-Bw&ved=0CDkQ6AEwAQ#v=onepage&q=Brillouin%20Energy&f=false >> >> If you take a look at figure 8 of the Godes patent application, you will >> see how he pulses the current through his micro wires [see item 0081 and >> onward starting on page 8]. Figure 9 shows an illustration of the pulsed >> current controller board. >> >> Or without diagrams: >> >> >> http://appft1.uspto.gov/netacgi/nph-Parser?Sect1=PTO2&Sect2=HITOFF&p=1&u=%2Fnetahtml%2FPTO%2Fsearch-bool.html&r=1&f=G&l=50&co1=AND&d=PG01&s1=robert&s2=godes&OS=robert+AND+godes&RS=robert+AND+godes >> >> >> Here is the patent description of the pulse generator with diagrams: >> >> http://www.freepatentsonline.com/7876133.pdf >> >> Note: This is different with what you(JoJo) are doing since you are using >> a decupled spark source. >> >> Godes is using a directly connected pulse current source. >> >> Cheers: Axil >> >> >> >> >> On Fri, Jul 13, 2012 at 6:58 PM, Jojo Jaro <[email protected]> wrote: >> >> ** >> Awesome explanation Axil. Very useful in directing my reactor design. >> >> So, Godes uses nanosecond laser. When translated to an electrical spark, >> how long should a spark be? I am thinking that it would take a moderate >> amount of time for the protons to be attracted to the lattice, travelling a >> distance of about 1-2 mm. I am thinking that that process should take at >> least a few tenths of nanoseconds. Hence, I am thinking of an electrical >> arc discharge of about 70 nanoseconds or so. >> >> What do you think? >> >> >> Jojo >> >> >> >> ----- Original Message ----- >> *From:* Axil Axil >> *To:* vortex-l >> *Sent:* Saturday, July 14, 2012 5:35 AM >> *Subject:* [Vo]:Nano pulses >> >> Nano pulses >> >> Robert Godes (aka qfman), founder of Brillouin Energy has come up with an >> important engineering idea in the field of LENR: high energy nano-pulses. >> >> Some background first, brief (picosecond or high femtoseconds) laser >> pulses cause Coulomb explosion. Depending on the type material being >> irradiated, enormous laser beam intensities are required (10–400 terawatt >> per square centimeter). >> >> This extreme power can only be delivered for a very brief instant of >> time. This powerful but narrow laser beam produces plasma of ionized atomic >> particles when a small amount of solid material explodes when hit with this >> high energy EMF pulse. >> >> A Coulomb explosion is a "cold" alternative to the dominant laser etching >> technique of thermal ablation, which depends on local heating, melting, and >> vaporization of molecules and atoms using less-intense longer duration >> laser beams. Extreme pulse brevity down only to the nanosecond regime is >> sufficient to localize thermal ablation – before material heating is >> produced and is conducted very far; the energy input (pulse) has long ended. >> >> Robert Godes does the same thing: extremely powerful cold energy >> delivery, in his reaction to keep his micro wires from burning up. His >> direct current pulse is only nanoseconds long but when they are in >> progress, they supply huge amounts of EMF to the lattice. >> >> For those using SWNTs in their reactions, they should draw a valuable >> lesson from Godes. They should pulse ultra-short high powered DC current >> down the SWNT via their substrate to produce maximum electrostatic fields >> but at the same time keep the SWNT cool and undamaged. >> >> How the reaction works. >> >> It has been observed that electron screening can reduce the coulomb >> barrier in the dust floating in space by many orders of magnitude: See the >> thread, Trojan Horse. >> >> There are large amounts of protons derived from high pressure hydrogen >> packed into the lattice of the reactor. The SWNT will induce an extreme >> electrostatically negative field in the lattice for a few nanoseconds. This >> negative EMF will draw these hydrogen ions (protons) near the now naked and >> ionized nuclei of the lattice. >> >> We now know that tunneling is proportional to the number of like positive >> charged particles that are close to the positively charged coulomb barrier. >> >> This large clustering of protons will aid one another through >> constructive Broglie matter wave interference to get one or two of their >> number to tunnel their >> >>
