ITFI20120130A1 - "A PROPULSION DEVICE OF THE ROTARY TYPE THAT GENERATES AN IMPULSIVE LINEAR PUSH FORCE" - Google Patents

Description

A PROPULSION DEVICE OF THE ROTARY TYPE IT GENERATES

AN IMPULSIVE LINEAR THRUST FORCE

Scope of the invention

The present invention relates to the technical sector relating to motors.

In particular, the invention refers to an innovative engine with reduced consumption and which bases its physical principle of operation on the "Byuon" theory, with particular reference to motion in cosmic space.

Brief notes on the known art

A recent cosmological physical theory is now known which includes among its direct consequences the possibility of using a new source of energy, the so-called "Byuon" theory. This theory is essentially based on the observation of a marginal anisotropy of physical space, which is associated with a cosmological vector potential Agavente the dimensions of the vector potential of a magnetic field.

This theory is for example explained in the publication "La Trama Unvelata", Ed. Polistampa, Florence, 2009, for example in chapter 1 in "Fundamental postulates of the Byuon Theory" and in many other publications listed below. Among these publications we can, for example, mention:

As for example described in chapter 3 of the publication "The unveiled plot", it is possible to obtain the generation of energy, in particular in thermal or mechanical form, under certain conditions by exploiting the principles of this theory.

The basis of the Byuon theory is the assumption, confirmed by experimental observations, of a marginal global anisotropy of physical space, in turn linked to a new fundamental vector constant, the cosmological vector potential Ag. Said cosmological vector Agha the dimensions of the vector potential of a magnetic field and the following coordinates in the second equatorial system: right ascension ~ 293 ° ± 10 °, declination ~ 36 ° ± 10 °, which in turn leads to the prediction of a new anisotropic interaction of nature, also called "the new strength ".

The new force acts when both of the conditions described below occur.

First condition: the modulus of the summation vector potential A∑, resulting from the sum of Age of the vector potentials associated with all known force fields - electromagnetic, gravitational, strong nuclear and weak nuclear - is reduced because a predetermined vector potential among those mentioned above assumes, at a predetermined instant, a sufficiently high value, a collinear direction and a naturally opposite direction with respect to the cosmological vector Ag

an algebraic reduction of the summation vector A∑ takes place which leads to a significant value of ΔΑ∑, or to a significant variation of the summation vector A∑.

Second condition: also the spatial gradient of the same quantity ΔΑ∑, that is with x indicating the generic coordinate in the space R <3>, must be sufficiently high.

If the above two conditions are satisfied, the new force F, expressed (in terms of only the first term of its series expansion) as

acts with maximum intensity along the

generatrices of a cone whose axis corresponds to the Age vector whose angular opening is 90 ° -100 °.

Note that the force fields at the origin of the two factors making up the new force can be completely different from each other: usually, the variation over time of the summation potential, ΔΑ∑, is generated by large-scale fields with very large values , such as the Earth's gravitational field, the intensity of which varies for example along a vertical path, or the geomagnetic field, which varies in the south-north direction. However, the spatial gradient can emerge from force fields on a local scale, such as magnetic fields originating from local variable electric currents and having absolute intensities much lower than the former but subject to very intense spatial variations and, as such, capable of acting as "amplifiers" of the effects of large-scale fields with respect to the local intensity of the new force.

This means that by simultaneously decreasing the modulus of A∑ and making the aforementioned decrease rapidly variable in space, thus giving rise at the same time to relevant values of both ΔΑΣ and of the relative gradient any body located in the region in which the modulus of A∑ is decreased will undergo the action of the new force, able to expel matter, and therefore mass, from the region with said modulus of A2 weakened.

So what happens will be that:

The matter placed in the region where the ΔΑ∑e variation of the gradient occurs will be expelled from the same region as a result of the action of the force in the case of liquids or gases, a fraction of the elementary particles will lose a part of their rest mass (~ 33 eV) and, by virtue of the known correspondence between mass and energy ΔΕ = Am-c <2>, the decrease in mass in the aforementioned region of physical space is transformed into heat.

The production of heat due to mass expulsion can therefore be used in equipment suitable for the generation of heat or which exploits the generation of heat to obtain certain technical effects (for example desalination or heating systems).

The generated force F can be used, by means of rigid solid bodies, for the construction of engines of an innovative nature.

In the experiments [15-17], conducted in the Institute of Atomic Energy (IAE) I.V. Kurchatov, a superconducting solenoid with induction of 15 T was used, and in the IOFRAN Institute, a resistive Bitter magnet with the same field. A special vacuum torsion balance was used for the measurements. The set of experiments in the IAE and IOFRAN showed that the value of the new force in the solenoid with magnetic field ~ (10-15) T is ~ 0.01-0.07 g, with test body mass ~ 30 g.

A large series of studies has been conducted on the effect of the new force on the β decay rate of radioactive elements [6, 18-21], which confirmed the existence of the new force of nature.

In the works [6, 21-23] the experimental studies of the new force are illustrated with the help of plasma apparatuses, conducted by different research teams in different Institutes. In these studies it was shown that matter is "pushed" out of the region with weakened (decreased) summation potential by means of the vector potential of the magnetic field associated with the plasma jet, along a cone with an opening around 90 ° -110 °. At the same time, it was also shown that in the second equatorial coordinate system, the vector Ag, directed along the axis of the aforementioned cone, assumes the following coordinates: right ascension a = 293 ° ± 10 °, declination δ = 36 ° ± 10 °.

In [6] the results of the experimental investigations of the characteristics of the new force are illustrated with the help of two different systems - the first system using one and two high precision "Sodin" quartz gravimeters (at SSAI MSU institute, Russia ) and the second system including two quartz resonators (FSUE TsNIIMASH institute, Russia). The resulting anisotropic effects in these experiments are also consistent with the action of the new force of nature and cannot be explained from the perspective of traditional physical representations.

Still in [6], on the basis of the new strength of physics, the nature of the earth's seismic activity is illustrated, and the results of the statistical analysis carried out on the georeferenced database of ~ 1500 earthquakes having a degree greater than 6-7 on the Richter scale (i.e. generally catastrophic). It emerges that in the Northern Hemisphere such earthquakes form a markedly anisotropic direction perpendicular to the vector Ag, which is consistent with the prediction of the dependence of the mass of the particles on the modulus of the summation potential A∑. In [6] the anisotropy of the spatial distribution of the eruptions on the solar surface and its relationship with the direction of the new force of nature is also discussed. In the papers [24, 25] the anisotropy of the velocity distribution of pulsars is investigated. In particular, it is illustrated how, in the process of the collapse of a supernova and the formation of a neutron star or pulsar, one or two jets of plasma are released within about 10 seconds; such jets, as suggested in [6], are produced by the action of the new force of nature and, according to Newton's third law, the pulsars - as indeed happens - move in the opposite direction to that of the new force.

In conclusion, any body placed in physical space, through the action of the potentials of the fields of its own elementary particles on the physical space itself, produces a sort of "hole" in it. The hole, in the region affected by a reduction of the modulus of the summation potential Αε, is due to the expulsion of matter because, as mentioned, the matter is "rejected" by the new force. The above "hole" corresponds to a kind of informative image of the object.

This theory is surprisingly applicable in the field of propulsion systems, especially space, land and marine engines.

At present, motorized systems are used which operate on a fuel basis. This is, for example, essential in the field of space flight where a strong propulsion is required and, above all, the only known propulsion system provides for the expulsion of mass, in the form of gases resulting from combustion. The motion of the object - spacecraft - occurs simply on the basis of the principle of action and reaction, that is, equivalently, of the conservation of momentum. The technical problems associated with this class of systems have been known for some time, namely the pollution, safety and consumption of fossil energy sources, which are in turn increased by the limited energy efficiency of the motion process. These problems are particularly evident in the case of the movement of objects through mass ejection (mainly apparatus for air and space motion, for example, rockets).

Alternatively, there are various classes of motors of a magnetic nature, in which a magnetic field is generated on an object, this field activating the motion of further bodies mechanically connected to said object.

Such engines can have applications both on Earth and in space.

However, all known classes of motors based on the creation of a magnetic field on an object present significant problems both of an energetic nature (high energy necessary to create the magnetic field) and, sometimes, connected to the difficulty of freely orienting motion in space.

Summary of the invention

It is therefore an object of the present invention to provide an innovative propulsion device which at least partially solves the aforementioned technical drawbacks.

In particular, it is an object of the present invention to provide a new type of propulsion device which is extremely efficient, which is of reduced pollution and which can be used in space applications in which, currently, the use of fuels is always necessary for the purpose of activating the motion. reaction.

These and other objects are therefore achieved with the present propulsion device according to claim 1.

The present propulsion device (1) comprises at least one motor (Ι ', 1' ') provided with a rotary shaft (4) rotatable around a rotation axis and at the end of which a massive body (5) is placed.

According to the invention, a control unit (10) is provided for controlling the rotation of the rotary shaft (4). This control unit (10) is programmed in such a way that each rotation of a complete revolution of the rotary shaft (4) occurs in a time range (Tl) less than or equal to 1 second, preferably less than 1 second and without lower limits except obviously the technical limits of the motor rotation speed. Furthermore, at the completion of each lap, there is a parking time (T2) of the massive body (5) at the starting point in a range between 0.01 sec and 0.05 sec, preferably 0.01 seconds.

The present invention is therefore based on the interaction of the spatial information image of an additional load (massive body) which - connected to a stepper motor and rotated by the latter - cyclically returns to its starting position, stationing there for a given period of time.

In this rotary system, a new force is generated because both conditions of ΔΑ∑ and of

are verified, as:

- The variation (decrease) ΔΑ∑ is generated, in the stationary position, by the complex of the intense vector potentials of the magnetic fields associated with the omnidirectional electric currents present in each of the additional bodies 5. The masses 5 are in fact constituted by electrically conductive materials in which passive currents circulate. The effect of decreasing the summation potential occurs only in the only position in which the additional body 5 stays for at least 0.01 seconds since in this position the direction of the vector potential of the magnetic field generated by a part of the passive currents is subtracted from the vector potential cosmological. The dwell time therefore allows the potential vector of the magnetic field to become effective. Throughout the residual circular path the same vector potentials of the magnetic fields are rapidly dragged into space by the rotational motion of the mass 5 to which they are connected and their effects on the summation potential are canceled out on average;

- the factor is generated, within each additional mass 5, by the very rapid variation in the space inside said mass, of the same electric currents and associated vector potentials of the magnetic fields: by rapidly varying the directions of these magnetic potentials in space, as a result of the rapid rotation, then also the relative effects on the summation potential assume a very high spatial gradient.

So, ultimately, the rotation with a single "stop" point means that only in that point a magnetic vector potential, opposite to the cosmological potential Ag, continues to be so for a time sufficient to decrease A∑, generating a significant one; for

instead, the rapid e is sufficient at this point

chaotic variation of the currents inside each additional body 5 following rapid rotation.

This apparatus does not need to consume fuel, as in [14], since it can be operated exclusively by electricity, called electricity in turn being able for example to be generated by the solar source or other non-thermal sources, as well as taken from batteries.

Furthermore, this apparatus minimizes the massive components and the dimensions of the apparatus itself. The energy of motion is extracted from the self-energy of elementary particles according to Einstein's formula E = me [4-6], associated with the formation of their physical space, as a result of changes in the summation potential of all structures of field produced in the matter constituting the body (elementary particles).

In the process of motion there is an exchange of momentum (momentum) between the object and physical space or, according to a common but improper term, with the "physical vacuum", to be understood as the state of minimum energy of the physical fields , from which elementary particles emerge and move [27], and which in turn emerges from the interaction of the byuons [4-6]. This type of theory is therefore applicable in the field of motors in order to obtain a motorized system that is eco-compatible, safe and efficient.

It is therefore evident that this propulsion device, moreover, is well suited to various applications.

In the marine environment, if applied to a ship, thrust generation involves moving the vessel without the need for a propeller. This means that there is a considerable structural simplification as well as completely eliminating the problems of corrosion and cavitation for the propeller.

In the space field, which is the one in which the present invention offers the most evident and greatest advantages, it is no longer necessary to consume fuel for the thrust reaction. Furthermore, the spatial motion, not acting external forces (friction), requires a minimum impulsive thrust to generate the displacement. Finally, being able to take all the energy, in electrical form, from the radiation produced by the Sun or other Stars, any limit in principle to the distance that can be traveled by a spacecraft, otherwise imposed by the exhaustion of the fuel available on board, expires. On land vehicles, the internal combustion engine can be replaced, as an alternative, with the device described.

Advantageously, the length of the rotary shaft from the motor (Ι ', 1' ') is comprised in a range between 4 cm and 6.5 cm, preferably 5 cm.

Advantageously, the motor (Ι ', 1' ') is a stepper motor, preferably of the electric type.

Advantageously, the propulsion device is symmetrical with respect to a vertical plane (a).

Advantageously, a first (1 ') and a second stepper motor (1' ') can also be provided, each one provided with a rotary shaft (4) rotating around a rotation axis, and at the end of which a body is placed. massive (5), said motors being placed symmetrically with respect to plane (a).

Advantageously, the two rotary shafts can be counter-rotating.

Also disclosed herein is a boat comprising a described propulsion device.

Also disclosed herein is a spacecraft comprising a described propulsion device.

In this way the only source of energy of said spacecraft, for the purpose of motion in cosmic space, will be electricity, produced on board by thermoelectricity or by conversion of the radiation originating from the Sun or from other Stars.

Also described here is a land or space wheeled aircraft comprising a described propulsion device.

Finally, the use of a propulsion device as described to generate a propulsion of a land, space or boat means of transport is also described here.

Brief description of the drawings

Further characteristics and advantages of the present device, according to the invention, will become clearer with the following description of some embodiments, given by way of non-limiting example, with reference to the attached drawings, in which: - Figure 1 schematically shows the engine according to the present invention;

- figure 2 shows an experimental diagram which measures the force applied to the motor arm at each rotation cycle during a "zero" test (absence of the effect);

- Figures 3 and 4 show a prototype of the propulsion device in a second embodiment;

- Figures 5 and 6 introduce further experimental graphs in the course of tests highlighting the predicted effect.

Description of some preferred embodiments

With reference to Figure 1, therefore, a propulsion device 1 according to the present invention is indicated.

For what has been said above in the known art, the engine is therefore based on the Byuon theory.

The motor, object of the invention, therefore provides a first stepping motor 1 'which rotates an arm 4, for example folded into an L shape but possibly also of another shape.

The arm 4 carries an additional mass 5 mounted at its end.

Again as shown in Figure 1, the stepping motor, for example electric, is then connected through appropriate wiring 8 to an electric power supply 9 of the stepping motor and to a control unit 10 of the stepping motor. The control unit, equipped with a special electronic controller, controls the rotation speed and the dwell times, as immediately explained below.

The system is symmetrical with respect to the plane a so that, in an opposite position with respect to said plane, a second stepping motor 1 '' is provided which, through the wiring system 8 (or appropriate independent wiring system), is always connected to the power supply 9 and to the control unit 10. The motor also has a connection to one of its arms which brings a massive element back to its end.

Being opposed to each other, the directions of rotation of the arms are opposite to each other in the sense that the arm 4, belonging to the motor 1 ', rotates in the opposite direction to that of the arm belonging to the motor 1' ', thus assuming the two aforesaid arms gyroscopic moments equal in absolute value but opposite in direction.

Initially the two masses, located at the ends of the respective arms, are therefore placed in opposite rotation.

The control unit 10 is programmed in such a way that, once a rotation has taken place, there is a pause lasting 0.01 seconds for each rotation cycle. Furthermore, the rotation must take place in such a way that the maximum return time of the mass to its initial position, therefore the maximum time to complete a 360 ° rotation angle, must not exceed 1 second and, preferably, must be less than one second. .

According to the above theory, this rotation within the time limit of 1 second and with a stop of about 0.01 seconds leads to an optimal generation of force with each revolution.

The distance of the mass 5 applied with respect to the axis of rotation around which it rotates must be of the order of 5 cm and in any case not significantly lower than said value.

The aforementioned preferential value for the rotation radius and therefore for a rotation diameter of the order of 10 cm - is such as to maximize the passive electric currents (and therefore the potentials of the magnetic fields) present in the additional load 5, thanks to the "channel of quantum information ", a direct consequence of the Byuon theory as it can be learned eg. in "La Trama Unvelata", Ed. Polistampa, Florence, 2009, for example in chapter 2 in "New quantum information channel (QIC). Communication in the 21st century", which allows to maximize the "connection" between elementary particles (electrons, in this case) activating the memory of the perturbations they produce on physical space for a period of time equal to at least one second. From the same theory derives the optimal range indicated between 4 cm and 6.5 cm.

According to the Byuon theory set out above, in a region where there is a variation of ΔΑ∑e of

there is mass expulsion as a result of the

generation of a new force

In this rotary system, a new force is generated because both conditions of ΔΑ∑ and of

are verified, as:

- the variation (decrease) ΔΑ∑ is generated, in the stationary position, by the complex of the intense vector potentials of the magnetic fields associated with the omnidirectional electric currents present in each of the additional bodies 5. The masses 5 are in fact constituted by electrically conductive materials on which passive currents circulate. The effect of decreasing the summation potential occurs only in the only position in which the additional body 5 stays for 0.01 seconds since in this position the direction of the vector potentials of the magnetic fields generated by a part of the passive currents is subtracted from the cosmological vector. Throughout the residual circular path the same vector potentials of the magnetic fields are rapidly dragged into space by the rotational motion of the mass 5 to which they are connected and their effects on the summation potential are canceled out on average;

- the factor is generated, within each additional mass 5, by the very rapid variation in the space inside it, of the same electric currents and associated vector potentials of the magnetic fields: by rapidly varying the directions of these magnetic potentials in space, also the relative effects on the summation potential assume a very high spatial gradient.

So, ultimately, the rotation with a single "stop" point means that only in that point a magnetic vector potential, opposite to the cosmological potential Ag, continues to be so for a time sufficient to decrease A∑, generating an "ΔΑς" "significant; on the other hand, the rapid and chaotic variation of the currents inside each additional body is sufficient at this point 5.

Remember that every body, for its own physical balance, is equipped with balanced internal currents and consequent magnetic potentials.

Figure 1 therefore shows the direction 7 of the force F that is generated on both masses due to the compound motion of rotation and stationing, which corresponds to the direction perpendicular to the plane formed by the line joining the centers of mass of the additional bodies 5 - which are the points of application of the force - and the line that contains the axis of rotation of the rotors.

The force is therefore simply a linear impulsive force applied to the center of gravity of the system and which in turn causes an accelerated linear translation of the same.

The resulting force is therefore applied in the center of gravity and with a direction belonging to the plane a of Figure 1. Figure 1 represents the force in an off-center position only for purposes of clarity.

The advantage therefore of a system with two stepping motors, and therefore of a symmetrical system, is that for which the system translates symmetrically.

However, it would take nothing away from realizing a non-symmetrical system consisting of a single stepper motor 1 which must be suitably balanced in terms of mass distribution, to ensure that the force generated does not cause a rotation rather than a translation.

It was then surprisingly experimentally verified that the optimization of the new incremental force F is obtained exactly with the aforementioned parameters, namely:

As mentioned above, the distance of the mass from the rotation axis of about 5 cm is preferably not less than said value, the admissible range being preferably between 4 cm and 6.5 cm;

Rotation speed such that a revolution angle is closed, during the rotation, in about 1 second and preferably in a period of time less than 1 second, the lower limit of this rotation period being determined exclusively by technical constraints to generate said rotation;

Waiting time before the new lap of about 0.01 seconds and in any case not less than this value, the admissible interval being preferably between 0.01 seconds and 0.05 seconds.

Figure 2 shows a graph obtained on an experimental motor consisting of a single stepping motor and an additional mass placed at the end of the arm.

The rotation was carried out according to the parameters described above, ie dwell and rotation times in optimal ranges.

Figure 3 and Figure 4 show a motorized system identical to that of Figure 1 except for the fact that it provides a single stepping motor and a single arm. Figure 3 and Figure 4 show the mass applied to the end of the arm.

In this case the motorized system was tied to the ground for experimental reasons.

As shown in figure 4, a series of sensors connected to a PC made it possible to process the graphs of the results of figures 2, 5 and 6.

With reference to the aforementioned graphs, time is represented along the abscissa axis with a scale of 400 points per second while the weight of the additional load 5 is represented on the ordinate axis (100 g corresponds to 2000 divisions). The graph shows the trend of the new emerging force F as a deviation of the measured weight with respect to the average weight at rest of the load.

The graph of figure 2, for example, was obtained by placing the additional load 5 in the starting and parking position in line with the action of the force F, with the arm placed on the horizontal plane, on which the scale was not able to measure strength ("zero" test). The rotation angle of 360 ° corresponds to the time interval between the time point 560 and the time point 812. The average value of the deviation of the weight (force) from its average value, measured at the position and at the moment of stationing, therefore at time point 812 (position "S2") it was just around 206.5 divisions (about 10 g).

The graphs of figures 5 and 6 were obtained by placing the additional load 5 in the starting and parking position in line with the action of the force F, with the arm along the vertical plane, on which the scale was able to measure the force .

For Figure 5, the rotation angle of 360 ° corresponds to the time interval between the time point 565 and the time point 810, i.e. about 0.61 seconds. The average value of the deviation of the weight (force) from its average value, measured at the position and in the moment of stationing, therefore at the time point 810 (position "S3") was around -4306 divisions, corresponding to approximately -215 g, that is a significant weight reduction (significant strength).

For Figure 6, the rotation angle of 360 ° corresponds to the time interval between the time point 360 and the time point 540, i.e. about 0.45 seconds. The average value of the deviation of the weight (force) from its average value, measured at the position and in the moment of stationing, therefore at the time point 540 (position "S4") was around -5944 divisions, corresponding to approximately -297 g. Evidently, the return of the load in a shorter time to its original position significantly increases, all other conditions being equal, the value of the force.

By generalizing the results of the experiments illustrated above as well as of further expressions whose description is omitted for the sake of brevity, it is possible to conclude that:

the force F increases with the decrease in the return time of the load to the original position, ie with the increase in the angular speed of rotation of the rotor 4 and the additional load 5;

on the other hand, if the return time of the load 5 to the original position is constant, the force F increases with the increase in the mass of the load and therefore, obviously, with the same mass of the load, the force increases with the number of loads;

the force F also depends on the nature of the load 5, ie on the substance that composes it, since the structure and distribution of the passive currents circulating in the load itself depend on this.

The motor, in the configuration thus described, is such as to receive an impulse (force F) at each stationing of each additional load 5 in the respective initial position: since the arm 4 is kept stationary during parking, thus inhibiting any rotation, the force F will have the effect of linearly accelerating the entire object 1 along direction 7; in order to obtain the desired value for the linear acceleration to be given to the object 1, with the same nature and mass of the loads, it is sufficient to appropriately vary the angular speed of rotation of the rotors 4 and therefore of the additional loads 5, and therefore the return time of loads 5 to their respective parking positions.

The force F does not therefore contribute to the rotation, which is regulated by the stepper motor, but acts exclusively to produce in the parking phases (0.01 seconds or more), an "impulsive" linear acceleration for the object as a whole. . In practice, the force is applied to the loads 5 but since these are forcibly fixed to the arm and therefore rigidly integral with respect to the object 1, the resulting force is applied, impulsively, to the overall center of gravity of the system.

Claims (10)

CLAIMS A propulsion device (1) comprising a motor (Ι ', 1' ') provided with a rotary shaft (4) rotating around a rotation axis and at the end of which there is a massive body (5) and characterized in that a control unit (10) is provided to control the rotation of the rotary shaft (4), said control unit (10) being programmed in such a way that each rotation of one complete revolution of the rotary shaft (4) takes place in a time range (Tl) less than or equal to 1 second, preferably less than 1 second, and at the completion of each lap there is a parking time (T2) of the massive body (5) at the starting point included in a range between 0.01 sec and 0.05 sec, preferably 0.01 sec. 2. A propulsion device (1), according to claim 1, wherein the length of the rotary shaft from the motor (Ι ', 1' ') is comprised in a range between 4 cm and 6.5 cm, preferably 5 cm. A propulsion device (1), according to claim 1 or 2, wherein the motor (Ι ', 1' ') is a stepper motor, preferably of the electric type. A propulsion device (1), according to one or more preceding claims, in which the propulsion device is symmetrical with respect to a vertical plane (a). 5. A propulsion device (1), according to one or more preceding claims, in which a first (1 ') and a second stepper motor (1' ') are provided, each one provided with a rotary shaft (4 ) rotatable around an axis of rotation and at the end of which there is a massive body (5), said motors being placed symmetrically with respect to the plane (a). A propulsion device (1), according to claim 5, wherein the two rotary shafts are counter-rotating. A boat comprising a propulsion device according to one or more preceding claims 1 to 6. A spacecraft comprising a propulsion device according to one or more preceding claims 1 to 6. A land or space wheeled aircraft comprising a propulsion device according to one or more preceding claims 1 to 6. 10. The use of a propulsion device according to one or more preceding claims from to 6 to generate a propulsion of a means of land, space or boat transport.