V.V. Roschin & S.M. Godin: Tests with Small Prototype of
Searl Effect Generator

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**V. V. ROSCHIN & S. M. GODIN**

**Searl Effect Generator**

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***New Energy Technologies*, Vol. 2, pp. 242-245**

**Testing of Small Prototype to Investigate
Searl's Effect**

**S. M. Godin and V.V. Roschin**

The authors go further in the research of possibility to
receive free energy by means of rotating constant magnets
(Searls Effect).

The aim of generator compact model (GCM) testing was studying
of possibility to produce a small and maximum cheap model, which
uses the ceramic magnets. Laboratory research of this model of
generator was aimed at the discovery of self-generation effects
and effects of weight change, which were already achieved on the
full-size generator [1].

A general view of GCM is shown in Figure 1. The generator
represented a mechanical system consisting of general
construction as a cylinder made of stainless steel divided by it
height in approximately two equal parts. The direct current
motor with collector was situated in the lower part; windings of
stator and rotor were connected in series.

**Figure 1**

![](fig1.jpg)

In the upper part of the construction on the axis of motor the
rotor is situated as a cylindrical ceramic magnet with a central
hole made on the base of cobalt-samarium mix. The magnet is
magnetized vertically and inserted into the steel fixture, which
preserves the magnet from destruction during the quick rotation.
Small magnetic rollers also made of ceramic magnets and
magnetized along the axis of rotation were placed around the
rotor. All 12 rollers were placed into the aluminum cylinders,
which preserve their brittle ceramics from mechanical impact
during the work in emergency conditions. The main idea of such
construction consists in the fact that in initial state the
rollers were attracted by the magnet of rotor to the side face.
Due to the repulsion of the rollers from each other, the
distance between them appeared automatically. With this distance
they uniformly distributed along the entire perimeter of the
rotor. During acceleration of the rotor the rollers diverge from
the rotor step by step and begin to run in the outside
cylindrical fixture, which is placed around the rotor at the
distance of 1.5 mm from the external surface of rollers in the
initial states. The height of the rotor magnet is 24 mm, the
diameter of the inside hole is 40 mm. All other geometrical
sizes and ratios are given in Figure 2.

**Figure 2**

![](fig2.jpg)

It was supposed that with a certain acceleration of rotation
the rollers would begin to rotate inside the outside fixture
with self-acceleration and would carry metal surface of rotor
device. This mode will be easy to discover due to the possible
decrease of the current consumed by the electric motor. Thus,
the aim of GCM testing was an attempt to find the features of
energy transformation of environment which lies in the
self-acceleration of the rotor device or other characteristic
effects concentric magnetic walls around the device and fall of
temperature) discovered already. The program of device testing
included registration of dependence of rotational speed of the
rollers along the outside fixture from rotation speed of the
motor.

Appearance of GCM is shown in Figure 3, when this device is
ready to test in laboratory conditions. GCM was placed on the
massive grounded steel plate. The power supply made in the form
of controlled transformer, isolating transformer, bridge diode
rectifier and capacitive filter were placed on the right.
Besides, the generator of reference frequency G3-112 and
frequency meter C3-54 were placed here.

**Figure 3**

![](fig3.jpg)

The 2-channel oscilloscope C1-99, digital combined unit TSH300
applied for the measurement of consumption current and power
supply TEC-88 (0-30 V, 0-2.5 A) applied for power supply of the
optoelectronic sensor of device rotation were placed on the
left. The measurement of rotation speed of the rollers was made
with an induction-type sensor, which was placed at the height of
the rollers, on the reverse side of the aluminum fixture. The
rollers after they separated from the rotor, rolled along this
fixture. During the passing of every roller by the
induction-type sensor, the impulse of voltage with the amplitude
of about 1V was produced. This voltage was supplied to one of
the inputs of 2-channel oscilloscope for direct observation on
the screen. A signal from the reference generator connected with
the frequency meter was supplied to the second input of the
oscilloscope.

Synchronization of scanning of the oscilloscope was provided
from the same reference signal. The frequency of the signal on
the reference generator was set to provide the most stable
immovable pattern on both channels of the oscilloscope. An
accurate measurement was made according to the data from the
frequency meter. Such method of measurement was chosen because
the applied collector motor of direct current ad permanent
deviations of rotation rate due to the change of voltage in the
mains, heating of bearings, collector and other reasons. All
this hampered the reception of an accurate value of average
rotation rate directly from the readings of the frequency meter.
It was necessary to divide the readings of frequency meter by 12
to receive the real value of rotation rate in rates per second
(rate of running around the fixture) of the rollers.

Measurement of rotation rate of the rotor was made in an
analogous way, but as a sensor we used the self-made sensor on
the base of optic pair IR emitter-receiver with an open optic
channel. The sensor was assembled on the textolite baseplate and
attached to the upper plexiglass head of GCM by means of usual
plasticine. Using this sensor we could quickly and effectively
adjust the necessary operating gap between the surface of
optoelectronic couple and surface of special metal disk with 25
dark and 25 light sectors applied on it. Thus, during one
rotation period of the rotor the photon-coupled sensor gave 25
impulses of voltage, which were transferred to the oscilloscope
for immediate observation. The appearance of photon-coupled
sensor or rotations attached to the upper plexiglass head of the
GCM unit is shown in Figure 4.

**Figure 4**

![](fig4.jpg)

In Figure 5 you can see the oscillograms of signal from the
photon-coupled sensor of rotation (upper beam) and harmonic
signal from the reference generator in the moment of coincidence
of frequencies with a one-phase accuracy. The real rotation rate
of the rotor was determined as a measured frequency (rate) of
generator divided by 25 (number of dark and light sectors on the
disk of rate controller).

**Figure 5**

![](fig5.jpg)

To receive reliable information on the characteristics of the
electromechanical system motor-permanent magnet of the rotor
there were made several bare measurements without installation
of the rollers. Measurements were made with the placing of
magnet north up and vice versa.

As we can see from the diagrams of dependence of the motor
consumption current from the applied voltage of power supply,
the strength of consumption current increases with the voltage
of power supply and reaches its maximum at 0.31 A with the
minimal possible rotation rate of the rotor. The strength of
consumption current does not depend on the polarity of
installation of the magnet in the limits of experimental
accuracy. For the given motor there is an area of minimal
consumption current, which lies in the diapason from 40 to 80 W.

We got similar curves of rotation speed for the cases of
different location of magnets of the rotor, which means the
independence of rotation speed from the polarity of the magnet
of the rotor.

The results of measurements of rotation speeds of the rotor and
rollers (given separately) are presented in Table 1.

**Table 1**

![](table1.jpg)

Here, as in the previous example, two cases are considered.
They are the case, when the magnet was installed with its north
pole up and an opposite case. The poles of the rollers change
accordingly. We should note that with the slow change of power
supply voltage, we practically always observed the instability
of the trajectories of the rollers and their tailing from the
operating surface, which led to the adhesion of one or some
pairs of the rollers together.

This fact distorted the pattern of measurements, and we had to
introduce correction factors during the calculation of rotation
speed of the rollers. These factors depend on the number of
fallen down or adhered rollers in pairs. This table was made
taking into account these correction factors and it is an
average one according to the results of five tests. As we can
see from the table, no self-acceleration of the rollers was
found. After the speed reaches a particular value of 8.5 rps,
the speed of the rollers stabilizes and does not increase in
spite of the increase of rotation speed of the rotor magnet.

Also we can see from Table 1 that the rollers always have a
tendency to retard and after the full separation with the
voltage of 20-23 V.

Concerning the polarity of magnet location we can say that it
does not influence the rotation speed of the rotor and rollers
in the limits of miscalculation in determination of speed and
voltage in the given experiment. Some differences in speed are
defined only by mechanical characteristics of the rollers and
surface o the fixture, which was used for revolving around. We
should say that the outside surfaces of the rollers and the
surface wer made of the same material (aluminum); thats why
they have a tendency of attrition even during one experiment (10
minutes). Due to this reason we couldnt get full reiteration,
but the accuracy was sufficient to establish the fact of full
absence of the self-acceleration effects and some differences
between polarities of installation of the rotor magnet and
rollers.

Unfortunately, we couldnt find any anomalies in the
temperature distribution and distribution of magnetic field
around the converter. Magnetic and heat walls discovered in
experiments with a big converter were almost absent around the
small device.

**Conclusion**

These experiments proved the point of view that during the
device operation the nonlinearity of the wave processes, which
take place in quantum medium (ether) plays the main role. It is
evident that there is some critical value of parameters in the
magnetic system of the converter (mass, induction of magnetic
field) and only in the case of excess of these parameters the
appearance of abovementioned effects is possible.

**References**

1  V. Roschin, S. Godin: An Experimental Investigation of
Physical Effects in a Dynamic Magnetic System; New Energy
Technologies, Vol. 1, July-August 2001, pp. 3-5.

**Editors Note:** -- Alexander Frolov --- I have to say
about my personal opinion of this experimental work. It is a
very strange project. I am not sure if these are 100% true
experimental results due to absence of real prototype at the
present time (Only the description of 7 KWt system was
published, It was built in 1002, according to S, Godin). On the
other hand, the theory of this energy converter and its
description by Godin and Roschin is in good correlation with
other theories on inner structure of physical vacuum. Faraday
Lab Ltd will develop this research direction and we hope to
present our own experimental results in the future.

![](roschgodn.jpg)

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