The Steorn Orbo motor replication by JL Naudin
created on december 26, 2009 - JLN Labs - Last update march 2, 2010
Toutes les informations et schémas sont publiés gratuitement ( freeware ) et sont destinés à un usage personnel et non commercial
All informations and diagrams are published freely (freeware) and are intended for a private use and a non commercial use.

Cliquez ici pour la version FRANCAISE


PROJECT LOG BOOK


Three KEY EXPERIMENTS to understand the Orbo motor principle

Overunity proof by Larsko ?
Loading test with a pickup coil connected to a High Power Leds panel with the Orbo motor v4
Read this patent: Substantial nullification of external magnetic fields and Lorentz Forces Regarding toroïdal inductors
Experiment on Viscous Remanent Magnetization (VRM) with the ferromagnetic core
New measurements after a fine tuning and a full alignment of the coils on the neutral line
Successful generation of the Orbo type pulses with Steorn motor V4
Motor V3: Canceling the Back EMF in the stator coils, How To...
Motor V3: COILS INDUCTANCE Vs ANGULAR POSITION of the rotor magnet
Test of shorting the two toroïdal stator coils at full RPM
Measurement of the toroïdal coil inductance Vs the angle of the rotor magnet
Measuring the current lag in the toroidal coils and fine tuning
The New Steorn motor V2 design and test
Understanding the Steorn effect, a very simple experiment
Dec 26, 2009 : My first Steorn motor V1 successful replication

The new Steorn magnetic motor shown on december 15, 2009 by Sean McCarthy in Dublin is composed by a rotor equiped with neodymium magnets and a stator which contains toroidal coils with a ferrite core.

The rotor magnets are attracted by the ferromagnetic material of the torus, so the magnetic potential energy is converted into kinetic energy of rotation. The ferrite will be magnetically polarized and will be temporarily transformed into a magnet of opposite polarity to that of the rotor magnet. So there is attraction but when the magnet is closest to the ferrite it is locked by the magnetic force and enable to exit. When the magnetic potential energy is minimal and when the kinetic energy is maximum (the nearest point of the magnet closest to the torus), a depolarization pulse is sent through the toroidal coils changing the orientation of magnetic domains (Weiss domains) of the ferrite, which frees the magnets.

I recall that there is no magnetic field outside a toroidal coil, it is commonly compared to a coil of infinite length. There is no direct interaction of the magnetic field of the torus with the magnetic field of the rotor magnets. The magnetic field of the toroidal coil is used only to depolarize temporarily the magnetization of the ferrite core. Thus, the magnetic force of attraction of the rotor becomes unbalanced (symmetry is broken), the magnetic potential energy during approach of the rotor magnet is less than the potential magnetic energy during the exit phase. This is therefore the purpose of "magnetic regauging" fully explained by Tom Bearden.

To summarize, we have a "non-reciprocal" and fully asymmetrical system. There is no counter electromotive force (back-emf) in the toroidal coils of the stator produced by the rotation of the rotor. The current required to get the temporary depolarization of the magnetic domains of the ferrite is fully independent of the mechanical torque produced on the motor shaft.

From the informations published on the Internet by Steorn, I have decided to reproduce this magnetic motor and, firstly, to check the observations and measurements presented in the video of December 15, 2009 by Sean McCarthy in Dublin.

The experiments proposed here and their explanations are only based on my personnal interpretation only of the Orbo working principle presented to the public through videos and photos by Sean McCarthy in Dublin and may be differ from the official Steorn explanations. These experiments presented here are the tests results of all my researches about the Orbo device from Steorn.



The previous Hall effect probe used to trigger the coils has been replaced by an optical sensor with black shutters for a better tuning.

Technical specifications of one toroïdal coil:
Ferromagnetic core (grade 3E25) specific inductance Al=3820 (23x14x7 mm)
wound CW with 7.5 m of 4/10 mm copper wire
Max inductance = 235 mH (far from the magnet)
Min inductance = 58.6 mH (close to the magnet)
Coil resistance = 1.4 ohms

Magnets specifications:
4 x 2 NdFeB magnets (Bremag 27) of 27 MGoe (208 kJ/m3) polarisation N-S outward.
Magnet size: diameter 22 mm, 10 mm thick

Rotor specifications:
Plastic cylinder: outer diameter = 100 mm, height = 50 mm
3 mm gap beetwen the rotor and the stator coils

Power supply: 10 V DC with 220 mA at 750 RPM


The latest model V3 is currently under test. This new design is more closer to the original demo rig version presented on dec 15, 2009 in Dublin by Steorn....

TEST 1: Shorting two toroïdal stator coils

In this test only the two toroïdal stator coils 1 and 3 are used to power the motor. The RPM is measured with an optical tachometer and the motor is only lighted with a DC battery powered halogen lamp while all the AC lights are switched off in the lab. At full and stable speed ( 690 RPM ), the stator coils 2 and 4 connected in series are shorted and the change of RPM is measured.

TEST RESULTS: At a full and stable RPM, when the toroïdal stator coils 2 and 4 are shorted with the switch, there is NO CHANGE in the RPM of the motor. Shorting the toroïdal stator coils has no mesurable effect on the RPM of the Steorn motor.

Below the video of the test

TEST 2: Stator coils INDUCTANCE Vs ANGULAR POSITION of the rotor magnet

The purpose of this experiment is to measure the variation of the inductance of the toroïdal coils of the Steorn motor V3 Vs the angular position of the rotor magnet. The inductance is measured with an inductancemeter Voltcraft LCR 9063 each 5° from 0° to 180°. The four toroïdal coils are connected in series.

Technical specifications of one toroïdal coil:
Ferromagnetic core (grade 3E25) specific inductance Al=3820 (23x14x7 mm)
wound CW with 7.5 m of 4/10 mm copper wire

Magnets specifications:
4 x 2 NdFeB magnets (Bremag 27) of 27 MGoe (208 kJ/m3) polarisation N-S outward.
Magnet size: diameter 22 mm, 10 mm thick


The total resistance of the four toroïdal coils connected in series is 4.5 ohms

Below the full video of the experiment :


Click here to see the full datasheet of the core material used in this test


On the diagram above the position of the toroidal stator coils and the magnets and the areas where the coils are powered are clearly showed.

TEST RESULTS: You will notice in the diagram above that, in this replication of the Steorn motor V3, the inductance of the toroïdal stator coils drops drammaticaly from 963 mH to 190 mH while the magnets approach to the coils. This inductance changing effect has been fully demonstrated by Sean McCarthy on his Orbo motor during his show "Cop>1" in Dublin on January 12, 2010...

TEST 3: Canceling the Back EMF in the toroïdal stator coils, How To ?

The purpose of this experiment is to demonstrate that Back EMF can be induced in the toroïdal stator coils when the coils are above and below the neutral magnetic line of the rotating magnets. You will notice that there is a very precise position where Back EMF is fully canceled.

To conduct this experiment, I have used my working replication of the Steorn motor V3 with its four toroïdal stator coils. I have added a fifth toroïdal coil as a Back EMF probe. This coil is able to move along a path parallel to the axis of the rotating magnets and above or below the neutral magnetic line. The rotor contains 4 pairs of NdFeB magnets with their North and South poles outwards (the magnet with the North pole outward on the top and the magnet with the South pole outward on the bottom).

TEST RESULTS: This simple experiment confirms that, when the toroïdal coils are placed above or below the neutral magnetic line of the rotor, Back EMF can be measured. This experiment confirms also that there is a very precise position where the Back EMF can be fully canceled, this can be done when the toroïdal stator coils are placed exactly in line with the neutral magnetic line of the rotating magnets.

Below, you will find the full video of this experiment :

TEST 4: Successful generation of the Orbo pulses in the Steorn V4


Now, my new toroïdal coils design of the Steorn motor v4 produces the same shape of the voltage and the current curves
than the original Orbo motor version from Steorn showed by Sean McCarthy...
You may notice that the current rises very fast (for the same inductance value) and the top of the curve is FLAT and HORIZONTAL....


It is very interesting to observe that the current is
constant during 72% of the pulse while the inductance of the stator coils increases from 246mH to 916mH...


Parametric Equation of this system

TEST 5: New measurements after a fine tuning and a mechanical alignement of the toroïdal coils

The pulse has been precisely tuned with the high power variable resistor and the coils have been finely aligned on the neutral magnetic line.
The results are now indeniable, look at the current and the power curves below, the current rises very fast and then the current curve is very flat and horizontal while the inductance of the toroïdal stator coils increases. So, no CEMF is produced by the motion of the rotor, there is no spike in the power calculated in real time by the high end digital oscilloscope....

Below, you will find a video of the test of the Steorn motor V4.1:

TEST 6: Experiment on Viscous Remanent Magnetization (VRM)

The purpose of this test is to measure the Viscous Remanent Magnetization (VRM) decay of the toroïdal ferromagnetic core used in my Steorn Orbo motor.

When one rotor magnet, freely attracted by the ferromagnetic material of the toroïd, lives the core, the ferromagnetic material of the core remains temporarily magnetized with the opposite polarity of the leaving magne, due to the VRM effect. When the next rotor magnet approaches to this magnetized core, it will be more attracted by this temporarily magnetization during its approach and thus it will get more kinetic energy.

(click on the picture below to know more)

TEST 7: Loading test with a pickup coil connected to a High Power Leds panel

The purpose of this test is to check the loading effect on the input current of the toroïdal stator coils of the Orbo motor v4. So, a pickup coil has been connected at 45° from the TDC. This pickup coil is a flat air core coil (600 mH) connected to a High Power Leds panel used as load.

The input current through the toroïdal stator coils is measured with an analog ammeter.

TEST RESULTS: At full and stable RPM, if the High Power Leds panel is switched ON, there is no change in the measured current at the input of the toroïdal stator coils.


At full speed, with the LEDs OFF, the measured current through the toroïdal stator coils is 400 mA.


If the High Power Leds panel is switched ON, the measured current through the toroïdal stator coils is still 400 mA.

Below, you will find a video of the loading test with the High Power Leds panel with an analog ammeter:

Below, you will find a video of the loading test with the High Power Leds panel with an digital ammeter:

OVERUNITY PROOF ? Successful Orbo replication by Larsko, measured COP = 4.75

Congratulations to Larsko, he has build a very frictionless replication of the Orbo motor. His measurements during the loading test has demonstrated an overunity effect.

See the Lasko measurement datas (feb 26, 2010) below :

The toroid core is a ferrite F-87A-H. permeability is 15000. Each coil has 200 turns of 23 AWG copper wire, 26 ft long. Each coil resistance is 0,5 ohm and the inductance of each coil is around 640 mH. When the motor runs, the total inductance of the 4 coils is between 2300 mH and 2400 mH.

Input power without load : 4 volt * 31mA = 0.124 watt. All the power is heat losses. Turn speed 1551 RPM
Input power with load: 4 volt * 32 mA = 0,128 watt. Input power increase only to 0,004 watt.... Turn speed 1240 RPM
Output Load on 9 Leds = 7.72 V * 2.99 mA = 0.023 W

Delta Power = 23 mW - 4 mW = 19 mW --->
19/4 = 4.75 ?

Comments from Jean-Louis Naudin : In the Lasko Orbo replication, it is important to notice that the COP of this device is less than one. The factor 4.75 is NOT A COP or the efficiency of his device. One of the most interesting thing in this good Orbo replication done by Larsko is that while 23 mW of power is collected at its output, only 4 mW is tapped at the input... This is a good example of a non reciproal effect.


Interesting documents :

Technical datasheets :

Patents :

Comments from Jean-Louis Naudin: Why this patent, below, is interesting for the Orbo motor ?

The patent below is very interesting because it says that in a common toroidal coil, each layer is equal to a "one turn coil" whose axis is parallel to the axis of the toroid. So, one layer of toroidal coil is equal to a flat coil of one turn and thus it can tap or produce EMF outside the torus. So, to counter this interference effect, the only thing to do is , for each layer of the toroidal coil, to wound a one turn flat coil along the circumference of the toroid so as to produce a magnetic field which nullify the virtual one turn coil created by each layer of the toroidal coil... This is very simple and a very important thing to do for canceling the weak CEMF induced in the toroid by the motion of the magnet and this is one of the most important key of the Orbo motor... 


Patent number: US5565835 (click on the picture to read the patent )

SUBSTANTIAL NULLIFICATION OF EXTERNAL MAGNETIC FIELDS AND LORENTZ FORCES REGARDING TOROIDAL INDUCTORS

Inventor: Lawrence R. Groehl
Assignee: The United States of America as represented by the Secretary of the Army, Washington, D.C.
Appl. No.: 260,151
Filed: Jun. 13,1994

Main and supplemental windings are combined in a toroidal inductor to subntially nullify Lorentz Forces on the main winding and the magnetic field thereof which passes externally from the inductor.

BACKGROUND OF THE INVENTION

Use of inductors or coils is well know as for storing electrical energy. As the electromagnetic parameters of inductors increase however, severe problems are encountered therewith, for example in power distribution systems of electric utilities. Because of Lorentz Forces which result from the interaction of currents with magnetic fields, structural integrity becomes a primary consideration. Magnetic fields which radiate externally from many inductors are also an important consideration because energy losses result therefrom, and a hazard to life and equipment.

Below, the Steorn motor shown to the public on december 15, 2009 in Dublin

I am not affiliated with Steorn Ltd. Orbo is trademarked by Steorn


Email : JNaudin509@aol.com


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