Post by
Wangotango67 on Nov 08, 2022 5:05am
RE- INVENTING - SOLAR PANELS
Problem with soloar panels involves - efficency.
Many of the photons bounce off / deflect and don't absorb.
Does one continue with this same modle or, rethink it ?
Let's first ask the question, is it really photons ?
Or more like electrons ?
Wink.
I'd make that bet and side with - photons are electrons.
Based on this principal, using electrons from the sun - how can one re invent solar panels ?
One would want to first design a device that crreates near full absorbtion.
Which involves - electron retention.
No deflection.
Which would entail,
using products that abosrb electrions, instead of trying to capture them.
Black or metallic products....
placed in suns rays whether summer or winter, will abosrb the thermal heat.
Is it really heat ?
Again... it's electrons being absorbed by the - chosen product - inwhich the electrons excite
and amass with in the - product - which saturate the product with electrons thus, creating an
overload of electrons = heat. And, most likely involves the thermal convection transmitted by sun.
- METAL ( BLACK )
- ELECTRON PHOTON ABSORBTION
- BOMBARDMENT / SATURATION OF ELECTRONS / EXCITEMENT
- RETENTION
- OVER RETENTION
- HEAT DISPERSMENT
3 MIN VIDEO - POP CAN - SOLAR HEAT
https://www.youtube.com/watch?v=hf-9M_WVuSM
210 - DEGREE HEAT.
How i see it ?
All about retention, not deflection nor trying to harnass or capture photons or electrons.
Creating a solar panel with a spin - focusing on the full heat / convection absorbtion would
increase the efficency by several multiples over - photon solar.
I envision similar apparatus' perhaps made by, magnesium,
but build in a commecial mode.
Other videos show a simple fan to assist in the dispersment of the heat from the cans.
I'd take it one step further...
And ask the question,...
If the solar heat is truly involving electrons.... then,
why not exploit the design one step futher ?
- use it for heat ( first phase ) using fan
- if made of metal, sponge some the electrons being absorb by the metal
and stream to battery cells for electricla conversion usage.
Metals
each have thier own unique molecular design.
Outter and inner valence orbits.
Magnesium is known to hold far more charge than other metals
Outter orbit rings is where most of the electron absorbtion or desorbtion occurs.
Accepting more electrons or the giving thereof.
Accepting - solar photon / electron - bombarding the metal - causing electron / heat retention.
Heat dispersion = by way of - heat given off of metal - electrons releasing
Sponging the electrons = capturing the electrons whilestil in the metal - simply linking a wire
to stream the electrons - into battery storage.
Metal when heated - expands.
Pointing to - more electrons being absorbed in outter rings of each molecule.
Electrons are filling the outter orbital rings.
Energy never goes away.
It simply converts.
Here's a neat lil experiment.
Turn a flashlight on.
Place over a solar powered calculator with calculator batteires removed.
The solar calculator works.
Which proves - energy from acid and metal inside the flashlight battery converts light
from the battery - light rays + heat - which streams energy in light ( electrons like the sun )
into the solar cells on the calculator. Energy conversions.
So.... could a metal solar panel outperform a silicon solar panel ?
Using thermal absorbtion - retention of electrons - and just how much more percentage
efficiency could be created vs standard solar panels ?
Designed properly, using select metals, and black to attract the thermal eletrons and perhaps more spectrums of light rays, i would say... absorbing the electrons from sun in a thermal contect is far better than relying on, hit and miss photon / electron in small solar cells.
One might want to perfect the product using - a mixture of products that could retain all the more
heat or electrons - maximizing the electron / heat load via metal mixtures with other elements exploiting the porosities = more energy storage.
Cheers....