Author: Dale
Date: 6/8/2012 12:47 am
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Our reactor is coming together fine and I wanted to share some information with the team regarding design considerations.
LENR Observations
Friday, June 08, 2012
1:01 AM
An overview of observations that were heard or seen weather or not factual nor conclusive have crossed paths during the past year of LENR. These can be noted now along a path to design a reactor equivalent to the technology involved.
Heat transfer from the reaction chamber through the copper tube and into the supporting framework of the reactor support needs to be controlled as to allow heat to build up within the (fuel) reaction chamber and or released swiftly, and allowed to flow into a directed specific area at any given time with an unlimited sliding scale of reference as to direction and speed of thermal heat energy encompassed within the reactor assembly.
Within our reactor there are three bands of cooling, the inner, outer, and mid bands which are polar arrays of ports with individual control for coolant (fluid) flow. When a chamber is running hot the three bands are separately controllable, as far as cooling fluid volume and can regulate singularly each direction the heat needs to transfer from or held into the source fuel chamber while in operation.
Hydrogen loading seems to be another variable factor toward efficiency of the LENR reaction and a need for pulsating the hydrogen, like a wave providing pneumatic physics in conjunction with thermal transfer. The wave exerts it's potential force onto the outer circumference of a fuel used and my preference is the ISOTAN 44 (Ni + Cu + Mn) of which I believe that was used by all successful LENR experimenters at this time. To much variable exists with the mixing of the powders and it seems that was meant to slow everyone else down attempting to promote LENR research, keep them busy with all the obstacles and that's a good reason for making the statements that if the reactor is torn apart it self destructs. They should have re worded it to be more technically correct. "If you tear the reactor apart the fuel rods disappear and no matter how hard you try to make the reaction work the fuel needs to be replaced and the fuel is essentially the reactor. Like purchasing a car with only one tank of gas and then after that's done gone the car becomes useless unless someone else supplies you with fuel.
Our reactor has the capability to maintain 10,000psi hydrogen pressure and pulsate it during the reaction process through a simple pre cup orifice chamber used commonly with gas/solid fuel reactions. This process also allows a pre heating of the hydrogen and directly dependent on the dimension, orifice size, and the area within the pre cup chamber. It is concluded that the higher the hydrogen loading pressure the more depth of penetration into the nano skeleton matrixes that have been grown onto the outer circumference of the ISOTAN 44 fuel rods. Obvious with the fuel rods contemplated is a consistency in exact percentages of elements used and that means to grow the nano structures is simply a current induced for a specific amount of time and a standard set for starting experiments.
Also the fuel wires used for the Celani et al. experiments were of nano size and the resistance nominally is around 1500§Ù per meter (39.37"), they were drooped down to provide a certain length and insulated with some type of wool. The problem is that; that design limits the amount of heat potential within the chamber before contamination begins and also provides a specific overall resistance for the current, as to limit the current potential.
Our reactor uses eight fuel rods per chamber and a method to tension at a specific chord (D) four larger diameter rods and four smaller fuel rods (dimensional cross section) as to form like a guitar. This allows the wires to be held in a position as to be isolated from the inside bore of the fuel chamber which is sweated into the heat exchanger (metal block) and provides the more positive common side of the electrical current flow system, and further clarified as the "high" side which is associated with a scope V+.
To insulate the wires from touching each another within our reactor fuel chambers we are using an isolation method and not a covering that will cause contamination within the fuel chamber or limit the core temperatures. Our reactor fuel chambers allow eight fuel rods of two dimensionally different diameters to be separated by the use of an eight faceted crystal that has been grown within a 2200C environment. This allows for no contamination within the fuel chamber while isolating the eight mismatched dimensionally fuel rods from touching one another and allowing the reactor to reach the meltdown temperature of the elements used such as the Ni and Cu ISOTAN 44.
If powder is anticipated the dc heating elements will provide the initial heating of the fuel as well as specifically regulate heat transfer into the multiple cooling port polar arrays called the cooling bands.
In effect the taut ISOTAN 44 fuel rods within each fuel chamber can be tuned to a specific audible acoustical frequency and when the reactions become optimum a specific sound will become evident, like a soothing tone. There are other reasons for the tautness of the fuel rods and they are mostly directed to consistency and a specific starting point established to begin a reaction.
The amount of current potential can be swiftly changed within our design due to the fuel rods are in parallel and furthermore are at a dimension to produce a nominal 12§Ù per meter of resistance allowing us to make swift changes to regulate a sustained reaction.
The features and attributes of our reactor are;
a. precise thermal (heat) transfer control using three bands of 25 cooling ports,
b. method and apparatus to pulsate hydrogen within a sealed chamber,
c. an operating internal gas pressure potential of 10,000psi.
d. an operating heat range exceeding the fuel potential (meltdown),
e. high flow of cooling fluid equivalent to 6.5" diameter pipe,
f. the ability to produce a resonating frequency for sustained fuel reactions,
g. the ability to operate in a totally submerged (fluid) environment,
h. the ability to be used as an engine and rotated within a matrix of linear actuators.
All parts and components of the reactor are replaceable, a totally workable reactor with the ability to be worked on easily and parts replaced by a regular mechanic trained to replace fuel rods and adjust tension by the use of the crystal isolator.
Our reactor literally can be tuned in with the usage of the thermal heat transfer and regulation methods as described in conjunction with the ability to use a current to induce heat into the fuel rods and provide means to oscillate the fuel rods at a specific acoustical frequency so that an optimum reaction can be easily documented and re produced over and over.
There are several physical elements obvious, pneumatic, fluid hydraulics, magnetic, electrical, and acoustical that are all variables for a optimized reaction that is self sustaining and our reactor accommodates the aforementioned needs for optimum performance of the heat engine. |
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