New magnetic simulations

We have released two new magnetic simulators

The first of them allows to calculate particle trajectories inside our reactors by using  multiwire simulation of thick coils with exact result needed in order to allow  compression of plasma using our EAC (Extreme Atomic plasma Compressors)

 

Also using elliptic integrals to have exact value of magnetic field it is designed a simulator subsystem that generate trayectories of particles to make kinetic diagnostic of accelerated plasma included speed and density over the 300 keV

 

The simulator will be used in the divertor design to eject particle debris after ignitions

New Magnet application

A Magnet application is released in order to help calculations of the  magnetic field inside reactors of the Liner class. Can be also used in Miranda reactors to help confine plasma before plasma heating in the  300KeV to 500keV region, divertor aparatus, plasma deflectors, electron deflectors, spin orientation, and electrokinetic compression

Problems with Miranda simulations

After the update of the Magnetic Simulator version 39 it was stated that the magnetic field is not enought to confine plasma over 400keV, so we have to study if more coils must be added.

Today we received the reactor chamber Mir-EP-02  and vacuum seals. the reactor chamber is compatible with Miranda 803 and 804 plasma heaters body but not with reactors of the Liner class

 

 

Clean reactions to be used

Advanced Ignition reactors will use clean reactions

The clean reactions are:

  • H+ Be9 -> Li6 + Alfa + 2.64MeV gain 528%
  • H + Li6 -> He4 + He3 + 4 MeV gain 800%
  • H+B11 -> 3 Alfa + 8.686MeV gain 12360%

Clean reactions are impossible to be performed using old electron heaters reactors as long as they radiates all the received energy with the 4TH power of the plasma energy and that reactions needs more than 350 keV that could not be reached in any reactor that heats thermally the plasma, as it was stated in our Pulsotron-2A reactor unless plasma density is lowered so much that very few reactions can be done as happened in the old reactors. So it was created new ion injection systems that allows to multiply ten times plasma energy by using ten times more power. Our reactor losses are in the range of a few hundred watts.

In the following figure appear the proton-beryllium reaction cross section. As larger the cross section is, more power can be extracted from the plasma.

Elena-56P20 Fusion Reactor

It is  a scientific thermonuclear fusion reactor designet to generate 3.6 MW. It works at a record energy of more than 300keV using a multistage electrostatic acceleration with extreme kinetic magnetic compression of the plasma and other fusion enhancement methods.

The 3.6MW design can be used to power trains, desalination plants, cut to 0 CO2 emissions, reduce energy cost in heavy industry, power ships and submarines. Can be upgraded to higher power levels to substitute obsolete fission plants

Advantages

Do not heats electrons to boost ion heating efficiency from 2.5% to over 95% accordingly our electrostatic simulator running on Elena reactor. Elena reactors can try ignition in 3 years and begin reactors production a year later.


Control system

Control of the system can be done remotely by using labview or other similar package in order to make secure control and maintenance


Plasma thrusters and Hyperloops

Using a Liner reactor as plasma thruster configuration can give 600 Newton thrust to power spaceships and Hyperloop trains.

The calculated thrust without fusion is 600 newtons, enought to power large spaceships, with fusion it is much higher to be used in space mining