Colloidal Silver
How to Make Colloidal Silver
The process has a reaction chamber which is blown glass with
a condenser attached. Distilled water is fed into the chamber
through the condenser in which 32F water is circulated, so the
the distilled water is cooled down to just above freezing. This
is fed into the reaction chamber where two silver electrodes are
inserted. The electrodes have quartz tubing over them so that
only about 1/8 inch is exposed, and 10,000 VAC @ 120 mA is applied.
The water is pumped through a flow meter which is set to 3.5 gallons
per hour.
The colloidal silver is drawn off the top of the reaction chamber,
and sent through a structuring magnet, then into a holding container.
Particle size runs from .001 to .02 microns. The concentration
is 5 ppm.
The rods are pure silver (.999). The Colloidal Silver is clear
unless a fairly large quantity is observed, in which a slight
light yellow tinge is observed. The near clear color indicates
very small particle size. The size vs. color is:
Clear - ionic and very small
Yellow
Orange
Red
Green
Blue
Violet - very large particles
The ELECTROCOLLOIDAL process creates an Electro-magnetic charge
that produces extremely fine silver particles, holding the silver
in suspension. This is called a "True Colloid of Silver."
Electrical methods have been used since the late 1800s. The currently
accepted method of electrolysis consists using silver electrodes
and either low or high voltage electricity.
The Bio/Tech News reports:
"The best and most effective method is the electrical process
since it is the only method which preserves the necessary homogeneity,
minuteness of granules, purity and stability to create a true
colloid."
When manufacturing Colloidal Silver through electrolysis, microscopic
particles of silver jump off the silver electrodes into water.
You can watch the process take place. When the water becomes electrically
charged, the positive (+) e/electrode bubbles and becomes a milky
mist of microscopic silver particles. The ultra fine silver dust,
consisting of minute clusters of atoms (some groups as small as
two atoms), makes the solution look milky. The electrical field
weakens the adherent that holds atoms together, and they become
loosely bonded or clustered. The electrical charge keeps the particles
in constant motion, causing the particles to propel themselves
through the solution, remaining in suspension. The electrically
produced clusters are so profuse that organisms connect with the
particles and die. If you do make your own formulas, place the
solution in a dark place for about twelve hours, giving any large
particles time to settle or fall out.
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