Re: Tesla and free energy

On Sep 10, 11:02 am, gb6726 <gb6...@xxxxxxxxx> wrote:
http://free-energy.ws/tesla.html

If heat pumps can produce energy from temperature differences,

I speculate that if there is a difference of other physics than
temperature,

energy can be made, as long as there is a greater source such as the
temperature

differences between water and air in Hawaii, as you wrote on your
page.

Let's introduce other natural physical differences than temperature.

How about atmospheric pressure and water pressure in the ocean?

One finds two different pressures, one deep under water, one in the
air.

If energy can be made from temperature differences through various

processes such as the Seebeck effect, how do we tap on to two places

where in one the water can produce high pressures on a bag of air deep

below, and little pressures above the water's surface. There is a
chance

that since we have unlimited pressures present under water and another

source above the surface that we can produce unlimited energy.

Imagine air driven into a water tank from below, and the air does not

need to travel down the water but takes a shortcut.

This is my research. Simply put, we compare what happens in the

heat pumps to gain a coefficiency of 3, and try to mimick it with a
different

property. Pressure is energy as it can set an object into motion as in
steam

engines.

gmbajs...@xxxxxxxxx

Continued: If you move air around between a warmer and a colder
source,

nothing will happen, you simply mix air.

Something needs to happen enable to get energy from two sources of
temperatures

other than simply mixing them. A compressor/decompressor is used in
air pumps,

and one arrives to the coefficiency of three as there is an energy
source in the

heat out there even if the temperatures are around freezing.

Pressure can set an object into motion, as seen in heat pumps. A
balloon

under pressure can blow air, there we find motion as the air escapes.
A

balloon builds up pressure in this example as air makes it inside.

Air deep under water is under pressure. But by moving air and

things around, we don't arrive to a coefficiency above 1.

a) we need to identify a source of energy. In heat pumps, one assumes

heat can be used as energy, either throough boiling water and then
using

top of the science means to turn steam into motion in the old ways but

above 33 percent steam engine efficiency to make free energy. Nuclear

powerplants that use multimillion dollar steam engines reported
reaching

36 percent efficiency. Orest Symko's invention at the University of
Utah

can turn heat into sound and sound into electricity. But results of
free

energy are far, a decade, two decades for now and any system might be

too expensive for commercial use.

How do you identify a source of energy in simple pressure, such as by

pushing a bag of water down in the sea, it gains pressure, and
pressure

can set things into motion without heat. It is the pressure that
steam

generates that allows moving steam engines. We can arrive to pressure

by pushing air under water. How can we utilize pressure? You place
three

tons weight on a very sturdy bag of air. Inside the bag the pressure
becomes

huge. So you need to find pressures in the environment as you find

temperature differences, you analyze heat pumps and follow through how

energy can become more than 100 percent efficient through moving heat

and using compression to obtain heat. Freon carries heat before and
after

compression or decompression. A cold refrigirant liquid can heat from
the

coils outdoors if there is cold outside or warm refrigirant liquid if
there is

heat outside.

The idea to make heat pumps efficient is *heat transfer*.

To transfer pressure is a whole different thing. We have a bag of air
under

water, if we transfer the bag out of water, the whole pressure
changes.

The idea becomes *transfering pressure*.

You can't just take a bag of air from under a heavy pressure under

water and move it. You have to have a process that accumulates
pressure

energy, transfer it and use it to make energy.

.

Relevant Pages

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