German TRESHALOV -- Damless Hydroelectric Station

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**German TRESHALOV*,
et al.***

**Damless Hydroelectric Station**

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[**http://erg.glb.net/\_private/publication.htm**](http://erg.glb.net/_private/publication.htm)  
[**http://www.sciteclibrary.ru/eng/catalog/pages/8986.html**](http://www.sciteclibrary.ru/eng/catalog/pages/8986.html)

**A Joke by a Great Scientist or Reality?**

by **German Treshalov**

The debate surrounding alternative energy
sources has not died down but is becoming more burning with
every passing day. This article partly (and maybe directly)
discusses the material published in issue No 3 of the
aAlternativnaya Energetika I Ekologiyaa (aAlternative Energy
and Ecologya) magazine in 2005, an article entitled aA new
generation of damless hydroelectric stations based on
hydro-energy unitsa .

**Background**

A group of engineers has constructed a hydraulic
turbine to receive energy from a free flow of water (a free
flow hydraulic unit). However, when its capacity was measured
it was established that it generated more energy than it was
designed for. It is well-known that a flow of  water has
kinetic energy that can be extracted (which is what free-flow
turbines do). However, it is impossible to extract all of its
kinetic energy. In order to do this, the flow should be
stopped completely and then it would cease to be a flow. That
is why the velocity of water flow at the exit from a working
unit of turbine is slower than its flow at the entrance a it
is precisely this difference that defines the efficiency of
any facility. When the velocity at entrance is 1 m/s and at
the exit it is 0.5 m/s we can extract 75% of kinetic energy
from the flow.

**(Ein  - Eout ) / Ein  = (Vin 2
a Vout 2 )  /  Vin 2**

(existing free-flow turbines have an even lower
figure)

As we have already mentioned, this facility
produced even a greater amount of energy than the total
kinetic energy of the flow.

Where does this additional energy received from
the facility come?

Does the flow of water have kinetic energy only?

(Here we do not consider the internal (thermal)
energy of water or the energy of the intermolecular and
interatomic bonds of water as a  substance.)

Let us try to answer these questions.

Let us take one cubic metre of water (with
dimensions of 1m \* 1m \* 1m) flowing with a velocity of 1 m/s.

There is no doubt about its kinetic energy,
which is:

**Ek = m \* V 2 / 2 
=  1000(kg) \* 1(m/s) 2  / 
2  = 500 (Joule )**

However, there is also pressure by the top
layers of water on the bottom ones (potential energy). If we
let this cube of water spread, then we can extract it.
Considering that the gravity centre of the cube is at the
middle of its height, that is h = 0.5 m, it is equal to:

**Ep = m\* g \* h  =  1000(kg) 
\*  9.8 (m/s2) \*  0.5(m)  = 
4900 (Joule )**

This means that the potential energy of this
cubic metre of water is up by almost 10 times on its kinetic
energy. It is easy to calculate that, at a speed of 0.5m/sec,
this difference will amount to almost 40 times!

In other words, we can see that a in addition to
the kinetic energy a the flow also has potential energy whose
magnitude depends on the flowas depth. But its exergy (that is
the recoverable energy which is able to actually work) is
equal to zero at regular conditions. After all, any volume of
water is surrounded by water with the same characteristics
(depth, speed, temperature). This can also be related to the
air. We know that the air surrounding us has a significant
amount of energy because the air has non-zero pressure and
temperature. But for the same reason mentioned previously, its
exergy is equal to zero and it is, therefore, useless from the
energy viewpoint (later we will see that it is not useless all
the time). (Brodyanskiy V.M aExergic analysis. Energy: the
problem of qualitya aNauka i Zhizna (aScience and Lifea) #3,
1982)

Now let us imagine that we are extracting part
of kinetic energy from a cubic metre of water, which is
flowing within a current, and use it to amove asidea the cubic
metre of water that follows it (downstream). That is we will
speed up the downstream cubic metre of water by slowing down
the upstream volume of water. As a result, a level difference
arises between them and potential energy emerges in the
difference between these levels, which can be extracted from
the current. The following question arises: will the amount of
the extracted potential energy be more, less or equal to the
energy used to speed up the second cubic metre of water a or,
in other words, the energy expended to increase its kinetic
energy?

Let us resort to mathematics.

As an example, we will consider a machine that
is shown as a diagram on Picture 1, which makes it possible to
speed up the outflowing stream of water by extracting part of
the inflowing streamas energy - that is, a machine with
positive feedback between the energies of the inflowing and
outflowing streams. By the way, a machine that works on this
very principle has been invented. It is this machine that our
story started with.

![](image004.gif)

**Explanations for Fig. 1:**

**1** - Working parts of the inflowing
stream of water;

**2** - Working parts of the outflowing
stream of water;

**3** - Working parts ensuring positive
feedback between the inflowing and outflowing streams of
water;

**4** - Mark showing the level of the
inflowing stream of water;

**5** - Mark showing the level of the
outflowing stream of water;

**6** - Channel bed

**H1** a Actual depth of the inflowing
stream of water

**H2** a Depth of the outflowing stream of
water

**V1** a Velocity of the inflowing stream of
water

**V2** a Velocity of the outflowing stream
of water

**h** a Drop between the levels of the
inflowing and outflowing streams of water

The device works based on the following
principle:

The working parts of the inflowing stream **1**
extract part of the kinetic energy from the stream and
transmit it - with the help of the positive feedback **3**
- to the working parts of the outflowing stream **2**,
which give the outflowing stream additional acceleration.

Because the amount of water entering the device
is equal to the amount of outflowing water, and the speed of
the outflowing stream is higher than that of the inflowing
stream, then the  sectional  area of the outflowing
stream will be less than that of the inflowing stream.

Therefore, its depth **H2** will be less
than the depth of the inflowing stream **H1** by the value
**h**. As a result of this, potential energy appears
between the different levels of the inflowing and outflowing
streams.

The deviceas energy balance is as follows:

**E = Ep1 + Ek1 a Ek2**

The total output of energy from the device is
equal to the potential energy of the difference between the
marks plus the kinetic energy of the inflowing stream and
minus the kinetic energy of the outflowing stream.  After
omitting all the computations, we have:

![](image005.gif)

or

![](image006.gif)

where **M** is the weight of the water
entering the device in a unit of time, which is equal to the
density of water multiplied by the active area of the
inflowing stream and multiplied by its velocity.

Then the most interesting aspect occurs. It can
be seen that the left side of the equation, which is in
brackets, will increase in a linear fashion when it depends on
**h** or in a hyperbola when it depends on **V2**,
whereas the right part will decrease, and in a parabola at
that. Which side will gain the upper hand?

Let us plot a graph showing energyas dependence
on the drop between the levels **h**. The graph will be
plotted to show the various levels of the inflowing streamas
velocity **V1** after designating it as a constant.

![](image008.jpg)

It is a paradox! The graph showing the energyas
dependence on the drop between the levels **h** has an
extremum. On the rising branch of the graph, the energy
balance will be positive (the power factor > 1), i.e. the
extracted potential energy will be mostly expended as kinetic
energy on speeding up the outflowing stream, and the device
will self-accelerate until it reaches the maximum.

The energy produced by the device at this point
will be several times the kinetic energy of the inflowing
stream - and under certain conditions, tens and even hundreds
of times!

The speed of the outflowing stream will be
significantly higher (2 to 3 times as higher at times) than
the speed of the inflowing stream. Therefore, the kinetic
energy of the outflowing stream is 4 to 9 times the kinetic
energy of the inflowing stream.

Furthermore, the graphs show that that not
everything appears to be quite right with the inflowing speed.
It also has an extremum. To see this better, let us plot a 3D
diagram.

![](image010.jpg)

Isnat it beautiful?!

![](image012.jpg)

This is the dependence on the outflowing speed.

However paradoxical this may seem at first
glance, but the diagrams show there is an optimal speed for
the inflowing stream. When it is exceeded, the deviceas power
capacity will sharply fall. This is due to the fact that a
significant amount of energy needs to be spent on speeding up
a stream that is flowing fast already.

Therefore, it can be seen that the device can
create a column of water for itself and is able to extract the
potential energy from an object (from a stream of water in
this case) without the expenditure of external energy.

Does this not remind you of something? People
who are knowledgeable about physics will immediately exclaim:
aWhy, this is Maxwellas demon!a Indeed! The much-discussed
Maxwellas demon that has thus far been elusive. Many people
will say that Maxwell proposed his ademona for thermodynamics,
and here you are dealing with hydrodynamics. Yes, but this
does not change the essence of the matter a we can extract
from an object (in this case, a flow of liquid) the potential
energy that cannot be extracted in normal conditions. And we
can extract it without spending anything (without even
building a dam!) at that. It is true that not all of the
potential energy can be extracted. Firstly, the depth of the
outflowing stream is not equal to zero. Secondly, part of the
potential energy extracted transforms into additional kinetic
energy splashed out with this flow. This energy is actually
even greater than the kinetic energy of the inflowing stream.
However, this is the reward we should give the ademona so that
it agrees to work for us.  As you see, the ademona also
awants to eata.

The question may arise: aHow does the outflowing
stream, which has a shallower depth, interact with the water
flow around it, which has a normal constant depth?a Here we
have to recall that the velocity of the outflowing stream is
higher than that of the surrounding medium and this creates
what is called in hydraulics ahydraulic jumpa, which equalises
the discrepancy between the kinetic and potential energies of
the two flows. This ajumpa is in essence surf, a vortex in the
flow.

The conclusions to be drawn from what has been
outlined above cannot be overestimated. In nature there exists
a process which makes it possible to extract energy which it
was impossible to extract in the past from any object - and
this process has been discovered! **This is the principle of
positive feedback that makes it possible to transfer energy
between different flows of energy sources**. There is the
possibility of extracting free, environmentally-pure energy
from the environment, which was predicted by the great
Scottish physicist James Maxwell back in 1871 in the form of a
jokey demon. Maybe it was precisely because of this that it
was always regarded as nothing more than a joke by the great
scientist. Or is it reality indeed?

It is not quite clear yet how it works with
thermodynamics and aerodynamics, but because this process
exists in hydrodynamics it should also exist in any other
branch of physics. There are some developments in
thermodynamics and aerodynamics already. Even if this process
is not found for them in the near future and it drags on for
decades, then at least applying its hydrodynamic
interpretation is already promising mankind huge dividends in
the form of free energy and an uncontaminated atmosphere

In the next article, we will discuss what seems
as the utopian idea (possibility) of using this principle of
extracting energy on cars, and a hypothetical engine for them.

**German  Treshalov** is a hydro-energy
engineer, head of the **E**ngineering **R**esearch **G**roup
to develop alternative sources of energy.

Copyright TiGER  erg@list.ru   
Translated by **Ascar  Jumanov,   Joanna
Lillis**   
01.08.06

*Note: applications have been submitted to
obtain international patents for the methods of extracting
energy and designing devices that use this method and
constructing such devices.*

V. Brodyanskiy aExergetic analysis. Energy: the
Problem of Qualitya, Nauka I Zhizn, No 3, 1982   
N. Shchapov aTurbine Equipment for Hydropower Stationsa,
Gosenergoizdat, 1961   
N. Gulia aIn Search of an Energy Capsulea, a web publication   
E. Oparin aPhysical Foundations of Fuelless Power-Engineering.
The Limitation of the Principle of Entropy Increasea, Moscow,
URSS, 2004   
L. Landau, A. Kitaygorodskiy aPhysics for Everyonea, Nauka,
1974

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**EP2019202**   
**METHOD OF EXTRACTING ENERGY FROM STREAM OF FLOWING
MEDIUM**

TRESHALOV GERMAN VLADISLAVOVICH   
EC:   F03B13/00; F03B13/08; (+1) 
IPC:   F03B13/00; F03B13/00   
2009-01-28

**Abstract** -- Die Erfindung betrifft ein
Verfahren zur Gewinnung von Energie aus einem freistrAPmenden,
horizontalen Strom eines Fliessmediums und ein
Berechnungsverfahren fA1/4r energieerzeugende Maschinen, die nach
dem erstgenannten Prinzip arbeiten. Das unterscheidende
Merkmal des beschriebenen Verfahrens besteht in der Verwendung
einer RA1/4ckkopplung zwischen der Energie des einstrAPmenden
Stroms und der Energie des herausstrAPmenden Stroms eines
Fliessmediums. Die RA1/4ckkopplung wird durch besonders
entwickelte Hydraulikmaschinen gewAcurrencyhrleistet. Eine
schematische Zeichnung einer derartigen Maschine dient zur
ErlAcurrencyuterung dieses Verfahrens.

![](image004.gif)

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