WO2007032696A2 - An antigravitational container and an antigravitational overcoat - Google Patents

Abstract

The object of the invention is an antigravitational container, whose construction has an optional shape, and an antigravitational overcoat assuming any shapes of the loads upon which it is put. Those devices reduce the weight of the loads placed within the container or wrapped up with the antigravitational overcoat almost by 100%, by making use of breaking up the gravitational bonds between the two firm walls of the container or the elastic wall of the antigravitational overcoat. The invention can be utilized to transport any kind of loads on land, water, in the air and in space, and to reduce the weight of the devices on board all the known vehicles. The cylinder-shaped antigravitational container (1) has a firm construction. The oval coat of the cylinder and all the sides are made from double bearing walls (2) . The container (1) has a closing flap (3) in which all the walls are also double. The container (1) has an outer wall (4) and an inner wall (5) . On the inner surface of the outer wall (4) there is a magnetic field generator (18) and/or an electromagnetic field generator, (16) and (17) , and there is a magnetic field generator (18) and/or an electromagnetic field generator, (16) and (17), placed on the outer surface of the inner wall (5) . The electrical conductors (6) and (7) of the electromagnetic generator are mounted on the diamagnetic or paramagnetic fillers (8), that are shaped appropriately. Permanent magnets (10) of the magnetic field generator (18) are mounted directly on the inner surface of the outer wall (4) and on the outer surface of the inner wall (5) . Ferromagnetics (9) are installed on the permanent magnets (10) of the generator (18) and on the diamagnetic or paramagnetic materials (8) of the electromagnetic field generator (17) . In another variant, between the inner wall (5) and the outer wall (4) there is an antigravitational overcoat (11) that has electrical conductors (12) . The antigravitational overcoat (11) is built from two elastic insulating coatings (13) within which there are electrical conductors (12) . Parts of the antigravitational overcoat (11) , properly connected with the base (14) assume any kind of spatial form (15).

Description

AN ANTIGRAVITATIONAL CONTAINER AND AN ANTIGRAVITATIONAL OVERCOAT

The subject-matter of an invention is an antigravitational container with an optional shape of construction, and an antigravitational overcoat adapting to the different shapes of the loads on which it is placed. Both the antigravitational container and the antigravitational overcoat diminish the weight of the loads placed within the container or wrapped with the antigravitational overcoat up to almost 100% by utilizing the break-up of gravitational links between the two rigid walls of the container or the flexible walls of the antigravitational overcoat.

The invention can be used to relocate any kind of loads on land, water, in the air and in the cosmic space, as well as for diminishing the weight of various devices on board of all the existing vehicles .

The phenomena of free energy were explained in a publication entitled "Selected Elements of the General Theory of Free Energy", by A. Ziobro, AGH Publications, Krakow 1997. The General Theory of Free Energy defines energy, identifies the particle of energy - its shape and kinds of charges it has - and describes the way matter is generated from energy i.e. the emergence of the elementary particles of matter (neurons, protons, elections and atoms) and the way they form matter by means of energy.

Gravitation is the most important phenomenon described by the General Theory of Free Energy which explains the emergence of gravitation on the atom level. The atoms of each element are composed of the nucleus (free energy- formed into rings which create quantum pipes) and of the cloud of free energy surrounding the nucleus. As the atoms are formed into matter by means of the shared parts of the free energy of the quantum pipes of the atom nuclei, part of the energy of the cloud surrounding the matter is forced outside the matter. The chains of free energy that are formed generate gravitation and have an effect upon the energy of each matter.

Research upon gravitation was started half a century ago, with the use of the Weber aerials and - more recently - with the Fairbank aerials, that are far more sensitive. The research facilitated the observation of explosions of supernova stars in various galaxies and made it possible to watch the sinking of space objects - the strongest sources of gravitational radiation. The existence of gravitational waves has also been confirmed by the research on double pulsars and on cataclysmic stars. The scientific and technological research that has been carried out has confirmed every aspect of the General Theory of Free Energy and has identified the following characteristics of the gravitational waves : a) gravitation waves spread with the velocity equal to the speed of the electromagnetic wave; b) gravitation waves spread along zero geodetic lines, called rays, in a way similar to electromagnetic waves; c) the polarization tensor of the gravitation waves is transferred along the ray; d) if monochromatic electromagnetic waves spread in an area with contiguous magnetic waves, they will generate a gravitation wave with the same frequency; e) if a monochromatic gravitation wave falls onto an are with weak electromagnetic field, it will generate an electromagnetic field with the same frequency. The state of the art includes a case of overcoming gravitation with a generated magnetic field with the electromagnetic induction equal 16 T (Tesla) . The experiment was carried out by Andre Geim at the University of Nijmegen and by Michale Berry from Brystol University, and was described in "European Journals of Physics", 1997 (vol. 18, pp. 307-313). Various different objects, such as water drops, tulips, nuts, a grasshopper or a live frog, were put into the state of weightlessness in that experiment.

At the present stage of technological development there are no devices used to diminish the weight of materials and no devices that would overcome the gravitation field while moving all kinds of loads over different distances on land, on water of in the air, so that the weight of the transported goods would diminish by almost 100%.

Nature of the invention consists in diminishing the transported loads in an antigravitational container by eliminating gravitation using magnetic or electromagnetic induction with a certain "B" value being several times lower than 16 T (Tesla) .

Permanent magnets made from obtainable alloys are used in order to generate a monopolar magnetic field necessary to eliminate the gravitational bonds, whereas the magnetic field obtained in this way is intensified by ferromagnetic materials that are generally available.

The electromagnetic field that is necessary for breaking generational bonds is obtained in various ways. It can be an electromagnetic field of a direct current, an alternating current, a diphase or a polyphase current, so that with a minimal decrease of overlapping current phases the field should have the required ^VB" value of magnetic induction. Both soft and hard ferromagnetic materials can be used to intensify the electromagnetic field. Combinations of magnetic and electromagnetic fields are also used in this invention to break the gravitation bonds in antigravitational containers .

The devices that generate a magnetic or an electromagnetic field with the appropriate magnetic or electromagnetic induction "B" on the container walls are called magnetic field generators or electromagnetic field generators. Magnetic or electromagnetic field generators consist of various different elements, depending on the way the magnetic or electromagnetic fields are generated.

According to the invention, the antigravitational container is a device using a magnetic and/or electromagnetic field to break the gravitation bonds, and therefore to diminish the weight of the load or loads placed within the antigravitational container up to 100%. The antigravitational container is a closed container of any shape, confined within double walls on all sides. On each of the walls there is an optional generator of monopolar magnetic and/or electromagnetic fields installed between the outer wall and the inner wall of the container. The side or the upper part of the container has flaps or doors facilitating loading unloading of any objects or goods. According to the invention, the shape which has the smallest total ratio of the wall surface to the volume is optimal for the antigravitational container. Containers in the shape of a sphere, a regular polyhedron, a cube or a cylinder of appropriate proportion of the height to the diameter are the most effective antigravitational containers. The shape of the container is also adapted according to the task desired and the kind of load transported. Irrespective of its shape, each antigravitational container has two bearing walls: an outer one and an inner one. The outer wall is made of a durable material, as light as possible, as it is not subject to antigravitation. It is made with the use of any light, durable and appropriately stiff materials, since the total weight of the inner wall of the container and the load is felt only when the antigravitation is turned off, i.e. during loading and unloading. The inner surface of the outer wall has a mounted generator producing a monopolar strong magnetic or electromagnetic field. The inner wall is made of strong, durable materials, resistant to damage, especially during loading and unloading the inner transporting compartment of the container. The external surface of the inner wall has a mounted generator producing a monopolar strong magnetic or electromagnetic field. In special applications of the present invention, the outer surface of the inner wall has mounted generators that produce a monopolar magnetic field and a monopolar electromagnetic field and/or the inner surface of the outer wall has mounted generators producing a monopolar magnetic field and an electromagnetic field. The generators of a magnetic field or an electromagnetic field placed on both walls of the antigravitational container are monopolar. Their charge is either "N" or "S" which makes them repel each other. Both the outer and inner walls of the container may take different shapes under the impact of weight, temperature etc. The planes of the magnetic or electromagnetic field generators placed on the inner surface of the outer wall and on the outer surface of the inner wall are parallel to each other, or are close to parallel, and are at a constant distance from each other, thus creating an empty space between them. The distance between the planes created by the generators of the magnetic and/or electromagnetic field placed on the outer and inner walls of the antigravitational container is between 0.1 mm to 20.00 mm. It is most appropriate that the distance should be from 0.3 mm to 5.00 mm. The interior of the container has devices that can be used to stabilize the load while there is no gravitation. Those devices are various kinds of belts, handles and other fasteners that do not allow the load within the container to relocate during the transportation.

The value of the magnetic and/or electromagnetic induction "B" produced by the magnetic and/or electromagnetic field generators that is needed to break the gravitation bonds is selected individually for each container and depends on the distance from the magnetic and/or electromagnetic field generators, the kind of container used, its size and shape.

The locking device of the container, which is a flap or a door, has two walls - an inner and an outer one, on which the magnetic and/or electromagnetic field generators are installed. The principle and the methods of breaking gravitation bonds between the walls of the flap or the door are the same as those in the trunk of the container. The special places that have to be protected in order to have the gravitation bonds broken upon the whole surface of the container are the places where the trunk contacts the flap or the door. According to the invention, in some types of container construction the points of contact are additionally protected with a ring or another element placed inside or outside the container trunk. That ring or that element generates a magnetic or electromagnetic field. The free space between the electrical conductors of the electromagnetic field generator is filled with diamagnetic or paramagnetic materials. These materials should have the magnetic permeability coefficient close to one. For this invention, copper with the permeability of μ=0.999991 is a good diamagnetic material, while aluminum with the permeability of μ=l.000021 is a good paramagnetic material.

Nature of an electrical electromagnetic antigravitational overcoat is its light and flexible construction. The antigravitational overcoat itself is a flexible antigravitational container assuming any desired shape .

According to this invention, the antigravitational overcoat is a device using an electromagnetic field to break gravitation bonds, and therefore to diminish the weight of the load placed inside it up to 100%. The antigravitational overcoat is used to transport loads with unusual shapes and/or with atypical dimensions, that are technically difficult or impossible to be placed in an antigravitational container, or when their relocation in an antigravitational container is not cost-effective. Due to the fact that the antigravitational overcoat can be adjusted to any size form or any shape of the loads, their external dimensions as well as their mass are of no relevance.

According to the invention, the antigravitational overcoat is made from any elastic materials that are good insulators of the electric current. The construction of the antigravitational overcoat consists of any number of elements that are connected in any possible way. The connection of particular elements facilitates free flow of the electric current between them. Each of the elements having the same structure has any kind of shape; the number and shapes of these elements are determined by the shape of the loads which will be covered by the antigravitational overcoat. Each of the elements of the antigravitational overcoat has no less than two elastic insulating coatings, within which there is no less than one layer of electric current conductors generating a strong electromagnetic field that is supposed to break the gravitation bonds. It is desirable that between the two external, elastic and insulating coatings, the overcoat should have two or more layers of electric current conductors separated from each other by additional elastic coatings which insulate the electric current while being permeable for the electromagnetic field. The distance between particular electrical conductors placed between the elastic external coatings of the antigravitational overcoat ranges from 0.0 to 10.00 mm. The most desirable distance should not exceed 3.00 mm. The antigravitational overcoat is joined together in any possible way that allows free flow of the electric current, with the base being in any shape. It is advisable that the construction of the base should be considerably hard and durable, so that heavy and atypical loads might be placed upon it. The base has two appropriately parallel bearing walls: the upper one and the lower one. The lower wall, which is not affected by antigravitation, has a stiff, durable construction. Any light materials can be used to build it, since the internal weight of the upper wall of the base and of the load is to be felt only when the antigravitation is switched off, i.e. while placing the load on the base and while removing it. From the side of the upper wall, the inner surface of the lower wall has a mounted generator producing a monopolar strong magnetic or electromagnetic field. The upper wall is made from durable strong materials, resistant to damage when the load put on or removed from the base. On the side of the lower wall, the inner surface of the upper wall has a mounted generator producing a monopolar strong magnetic or electromagnetic field. Both the lower and the upper part of the base of the overcoat cannot be deformed under the impact of weight, temperature etc. The surfaces of the magnetic field or the electromagnetic field generators placed on the inner surface of the lower wall and the inner surface of the upper wall are parallel or close to parallel and maintain a constant distance from each other, creating an empty space between them. The free space between the electric current conductors of the electromagnetic field is filled with diamagnetic or paramagnetic materials. Those materials should have a magnetic permeability coefficient close to 1. Examples of such materials are diamagnetic copper, with the permeability of μ=0.999991 or paramagnetic aluminum, with the permeability of μ=l.000021. It is desirable, that the current-powered electromagnetic antigravitational overcoat, as described in the invention, should be the generator of the electromagnetic field of the base.

The base to which the antigravitational overcoat is fixed has fasteners to fix and stabilize the load at the time there is no gravitation. Those are various kinds of belts, catches and other fastenings that do not allow a load placed on the base to move during the transportation. Together with the base, the current-powered electromagnetic antigravitational overcoat forms a special kind of antigravitational container that has no fixed dimensions and therefore adjusts its shape to the loads that it helps to transport.

It is desirable that the particular elements of the antigravitational overcoats that are to be connected with one another and with the base should have specially designed zippers. While zipped, the zipper locks, due to their construction, provide durable connection, in every single place, of the particular current conductors installed in each layer inside the overcoat. The construction of the overcoat has additional protection at the points of contact of the connections of particular parts of the overcoat. That protection creates a layer of an additional generator of the electromagnetic field, covering the connections of the particular parts of the overcoat.

In order to produce a monopolar magnetic or electromagnetic field with the appropriate "B" level of magnetic induction, each antigravitational container (as described in the invention) has a mounted generator of a magnetic or electromagnetic field.

A magnetic field generator, mounted on both the inner surface of the container's outer wall and on the outer surface of the inner wall, is composed of permanent magnets and ferromagnetic materials; it does not need electric power - or needs only a minimal quantity of it, as much as is necessary to break the gravitational bonds. Due to the ferromagnetic substances installed, the magnetic field is magnified several hundred times as compared to the initial field generated by permanent magnets.

The electromagnetic field generator is made from electrical wires supplying power, from power conductors generating the electromagnetic field, ferromagnetic elements or alloys magnifying the electromagnetic field, and from diamagnetics or paramagnetics filling the free space around the electric conductors. In order to magnify the electromagnetic field, it is advisable to use soft and hard ferromagnetic materials. The elements and soft ferromagnetic alloys are low-alloy steels, steel-silicon alloys, iron-nickel alloys, cobalt-nickel alloys and others. Hard ferromagnetics are commonly used materials used to make permanent magnets. These are such elements as iron, cobalt, nickel or carbon steel alloys, chromium steel, wolfram steel, cobalt steel, other special alloys, such as powder Fe, Ni, Al, Co and Cu materials, ferrites, powder oxide materials, ironless alloys etc.

The electromagnetic field generator mounted on both the inner surface of the outer wall of the container, and on the outer surface of the inner wall is supplied with direct or indirect current from a power generator, a battery or batteries or from any other source that is able to provide power to generators of the electromagnetic field.

The generator of the electromagnetic field installed on the inner surface of the outer wall is connected to any- kind of electric source or power generator. The electromagnetic field generator mounted on the outer surface of the inner wall of the container is powered from inside of the antigravitational container. The source of the electric current can be batteries or other sources of pre-accumulated electricity. It is advisable that the electromagnetic field generator mounted on the outer surface of the inner wall should have electrical supply from common hydrogen batteries. External impulse supply can be used. The time of transferring an electric energy impulse from the outside ranges from 1/50 sec. to 1/200 sec, whereas the same impulse should be repeated anywhere from ten to twenty times per second, no more than twenty times per second. The external electric impulse should be short enough not to stop the ongoing process of breaking the gravitational bonds between the surfaces of the generators of the electromagnetic field of the container. That impulse is caught by energy batteries mounted inside the charger of the container. The number and the capacity of the mounted batteries should guarantee the continuity of the performance of the electromagnetic field generator. The optimal number of batteries to be installed is 10 to 15. The batteries should one by one release the received energy. This way of releasing energy by the batteries extends the time of activity of the accumulated energy considerably, so the decreases should maintain the ^ΛλB" value of electromagnetic induction necessary to break the gravitational bonds .

Ferromagnetics intensifying the effect of the electromagnetic or magnetic field are installed in the inner part of the container, in order to minimize the required power supply. The weight of the ferromagnetics mounted on the inner wall is subject to antigravitation. It is advisable to mount the ferromagnetics strengthening the effect of the magnetic field or the electromagnetic field on both walls of the antigravitational container. Then the perceptible weight of the container will be increased by the weight of the ferromagnetics that are placed on the outer wall, because the outer wall is not subject to antigravitation. Gravitational bonds are broken upon the whole surface of the container. In order to break the gravitational bonds, magnetic and/or electromagnetic field generators are mounted on the walls of the container. The physical unit characterizing the magnetic field and the electromagnetic field is the density of the force lines of the magnetic or electromagnetic field, called magnetic or electromagnetic induction "B". Gravitation bonds are broken:

1. By the activity of an electromagnetic field obtained by using the effect of direct or indirect current in the electric current twists forming a coil. Electric current conductors, placed one by one, form a coil increasing the density of the force lines of the electromagnetic field. The closer the electric conductors of the coil are from one another, the more they increase the density of the force lines of the electromagnetic field. It is advisable that the distance between the conductors in the coil should from 0.0 mm to 5.0 mm. The twists of the electric conductors that form the coil are placed on the inner surface of the outer wall of the container and on the outer surface of the inner wall of the container. The free space between the particular twists of the coil and around each of the current conductors is filled with diamagnetics or paramagnetics . The electrical conductors of the coil and the paramagnetics form an electromagnetic field generator of the first type. The electric current in the twists of the coil placed on the outer wall and on the inner wall of the container run in the opposite directions, and the electromagnetic fields generated by the twists of the coil repel each other. For breaking the gravitational bonds, the optimal distance between the surfaces of the electromagnetic field generators placed on the outer and the inner walls is the distance from 0.3 mm to 5.0 mm. That distance is the free space necessary for the process of breaking the generational bonds.

2. By the electromagnetic field intensified by ferromagnetics, generated by a direct or indirect current in the twists of an electric conductor forming a coil. The electric conductors, placed side by side, cause an increase of the density of the force lines of the electromagnetic field. Bringing the conductors closer together increases the density of the force lines in the electromagnetic field. It is advisable to place the conductors in the coil from 0.0 mm to 5.0 mm from one another. The twists of the electric conductors forming the coil are placed on the inner side of the outer wall of the container and on the outer side of the inner wall of the container. The current runs in the coils in opposite directions. The electromagnetic fields generated by the coil repel each other. The free space between the electric conductors forming the twists of the coil is filled with diamagnetics or paramagnetics . In order to intensify the magnetic field, ferromagnetics are put on both coils, which increases the density of the force lines of the electromagnetic field. The ferromagnetics are usually fixed to diamagnetic or paramagnetic materials . Electric conductors of the coil and the ferromanetics form a generator of the electromagnetic field of the second type.

Using ferromagnetics we have great savings on the use of the electric current necessary to break gravitational bonds. The optimal distance between the surfaces of the electromagnetic field generators mounted on the outer and inner walls ranges from 0.3 mm to 5.0 mm. That distance is the necessary free space in which the process of breaking the gravitational bonds takes place.

3. By a magnetic field strengthened by ferromagnetics. Breaking gravitational bonds in an antigravitational container consists in obtaining a "B" type magnetic induction by means of a magnetic field. Permanent magnets are used to generate a magnetic field. They are placed on the inner surface of the outer wall of the container, and on the outer surface of the container's inner wall. Ferromagnetics are mounted on permanent magnets, placed on the walls of the container, magnifying the electric field generated by the magnets. Together with the ferromagnetics, the magnets create - upon the walls of the container - a magnetic field generator of the third type. The optimal distance between the surfaces of the magnetic field generators installed on the inner surface of the outer wall and the outer surface of the inner wall ranges from 0.3 mm to 9.0 mm. That distance is the necessary free space in which the process of breaking gravitational bonds takes place.

4. By the simultaneous action of magnetic and electromagnetic fields.

A useful variant of the antigravitational container as represented in the invention is one with a second type generator of electromagnetic field installed on the inner surface of the outer wall of the container (the generator consists of a coil, paramagnetics or diamagnetics, and ferromagnetics strengthening the electromagnetic field) and a third type magnetic field generator consisting of permanent magnets and ferromagnetics strengthening the magnetic field. The antigravitational container, with an electromagnetic field generator of the second type on the outer wall, and a magnetic generator of the third type on the inner wall, is the most effective form of the invention. The magnetic field generator placed on the inner wall of the container does not need power supply. The weight of the installed generator magnets and the ferromagnetics, together with the inner wall of the container and the load placed within it, are subject to antigravitation. The weight is perceived only while the antigravitation is switched off - i.e. while the container is loaded or unloaded.

5.By a single electromagnetic field generated by power conductors placed in the current-based electromagnetic antigravitational overcoat. The method of a single electromagnetic field is based on the same principle as the double electromagnetic field. The density of the force lines of the field - i.e. electromagnetic induction with the magnitude *B", necessary to break the gravitational bonds - occurs everywhere within the elastic antigravitational coat, and also on the connections of its particular elements. However, obtaining the appropriate "B" value of electromagnetic induction that is necessary to break the gravitational bonds requires much higher intensity of the electric field and the use of more electric energy than in the case of a double electromagnetic field.

It is advisable for this invention to have, between the inner and outer walls of the antigravitational container, a current-based electromagnetic antigravitational overcoat - as described in the present invention - installed as a generator of a monopolar electromagnetic field. Since the antigravitational overcoat is actually an elastic antigravitational container shaped in any desired way, it can be installed on one of the walls being the base of the antigravitational container and therefore creating a base for the antigravitational overcoat. After mounting the overcoat, the antigravitational overcoat is wrapped tightly all over the container, which then serves as a regular container used for transportation. The working principle of the antigravitational container consists in placing inside it a load of desired volume or appropriate capacity. After closing the inside of the loaded container, the monopolar magnetic or electromagnetic field generators installed between the container walls are switched on, and their activity around the whole container results in breaking the gravitational bonds. The load within the inner walls of the container, as well as the inner walls themselves, has been cut off from the operation of gravitational forces. The actual weight of the loaded antigravitational container is the weight of the outer wall of the container and the devices mounted on the outer walls. While the generator of monopolar magnetic or electromagnetic fields is working, the loaded antigravitational container can be moved in any way, by any kind of transportation, over any desired distance and using minimum amounts of energy for the transportation.

An antigravitational container, with this type of construction, has a very wide range of applications. It can be used as a driving device in a gravitational engine. The engine uses antigravitation when the container is going up, and its weight while going down. The antigravitational container can also be used to relocate heavy loads in space, in aviation, in sea and land transportation. The antigravitational containers reduce the weight placed inside almost to zero for any kind of vehicle. The only load of the vehicle is the weight of the outer wall of the antigravitational container. The use of antigravitational containers as antigravitational chambers is particularly important for crews of space and aviation vehicles, as the crew does not have to experience the load factor during the launch and the landing, and during each change of speed and direction of the flight. The weight of the devices on board and of the fuel in space and aviation vehicles will be diminished, which in turn will reduce the weight of the vehicle during the start and during the flight. The advantage of the antigravitational container, as presented in the invention, is its very wide application, especially in any kind of relocation and transportation of super-heavy loads over any distance on land, in the air and in space, with a reduction of the energy used for the transportation from 30% to 95%. The antigravitational container can also have various other applications in which the alternative use of gravitational and antigravitational forces will result in the transformation of that impact into another kind of energy produced - the best example being the gravitation engine.

An example of the construction of an antigravitational container, as described in the invention, is presented on drawings. Fig. 1 shows the antigravitational container in the shape of a cylinder. Fig. 2 shows a cross section through the outer and inner walls of the antigravitational container, indicating the distribution of the electrical conductors as well as the diamagnetic and paramagnetic materials. Fig. 3 presents a cross section through the outer and inner walls of the antigravitational container with the distribution of the electrical conductors, as well as of diamagnetic, paramagnetic and ferromagnetic materials. Fig. 4 shows a cross section through the outer and inner walls of the antigravitational container with permanent magnets and ferromagnetics placed on both sides of the container. Fig. 5 presents a cross section through the outer and the inner walls of the antigravitational container, with the electrical conductors of the electromagnetic field generator, together with diamagnetics and ferromagnetics, placed on the inner surface of the outer wall, and with permanent magnets of the generator of magnetic fields, together with ferromagnetics, on the outer surface of the inner wall. Fig. 6 shows a cross section through the outer wall and the inner wall with an antigravitational overcoat placed between the walls. Fig. 7 presents an antigravitational overcoat, and an antigravitational container in the shape of a single-masted tent built from that overcoat.

Antigravitational container 1 has a firm construction, whose oval cylinder coat and all the sides are made from double bearing walls 2. Container 1 has a closing flap 3, whose walls are all double, too. Container 1 has an outer wall 4 and an inner wall 5. A magnetic field generator 18 and/or electromagnetic field generator 16 and 17 is/are placed on the inner surface of the outer wall 4, while a magnetic field generator 18 and/or electromagnetic field generator 16 and 17 is/are placed on the outer surface of the inner wall 5. Current conductors 6 and 7 of the electromagnetic field generator are installed in the appropriately formed diamagnetic or paramagnetic fillers 8. The permanent magnets 10 of the magnetic field generator 18 are mounted directly on the inner surface of the outer wall 4 and on the outer surface of the inner wall 5. Ferromagnetics 9 are installed on permanent magnets 10 of the magnetic field generator 18 and on the diamagnetic and paramagnetic materials 8 of the current conductors 6 and 7 of the electromagnetic generator 17. In another solution, between the inner wall 5 and the outer wall 4 there is an antigravitation overcoat 11, which has parallel current conductors 12. The antigravitational overcoat is made from two elastic insulating coatings 13, inside which there are current conductors 12. Properly connected with the base 14 of the antigravitational overcoat 11, they have any kind of spatial form 15.

Claims

PATENT CLAIMS

1. A prism-shaped antigravitational container, filled with any kinds of loads, is characterized in that antigravitational container being a closed container (1) of any shape, limited on all sides by double parallel, or close to parallel walls (2) situated at the same distance from each other - the outer wall (4) and the inner wall (5); between the walls (2) and/or on the inner surface of the outer wall (4) and on the outer surface of the inner wall (5) of the container (1) there is a generator of any kind of either monopolar magnetic fields (18) and/or monopolar electromagnetic fields (16) and/or (17) with the magnetic and/or electromagnetic induction "B"; the lateral or upper part of the container (1) has flaps or doors (3) which close the container (1) ; and this closing device has two walls: the outer one (4) and the inner one (5), which have generators of monopolar magnetic fields (18) and/or electromagnetic fields (16) and/or (17) installed; and the distance between particular electrical conductors (6) and (7) ranges from 0 to 20.00 mm, while the free space between the surface of the generator (16) and/or (17) and/or (18), installed on the inner surface of the outer wall (4), and the surface of the generator (16) and/or (17) and/or (18) installed on the outer surface of the inner wall (5) ranges from 0.1 mm to 20.00 mm.

2. A container as in claim 1, characterized in that the free space between the surface of the generator (16) and/or (17) and/or (18), mounted on the inner surface of the outer wall (4), and the surface of the generator (16) and/of (17) and/or (18), mounted on the outer surface of the inner wall (5), ranges from 0.3 mm to 5.0 mm.

3. A container as in claim 1, characterized in that the shape of the container (1) has the smallest total ratio of the wall surface to the volume.

4. A container as in claim 3, characterized in that the container (1) has the shape of a sphere, regular polyhedra, a cube or a cylinder with an appropriate proportion of the height to the diameter.

5. A container as in claim 1, characterized in that the permanent magnets (10) and hard or soft ferromagnetics (9) are the generator of monopolar magnetic fields.

6. A container as in claim 1, characterized in that the generator of monopolar electromagnetic fields (16) is built from electrical conductors (6) and (7), diamagnetics or paramagnetics (8) , and the generator of monopolar electromagnetic fields (17) is built from electrical conductors (6) and (7), diamagnetics or paramagnetics (8), as well as ferroimagnetics (9) - whereas the generator (16) and (17) is powered by direct or indirect current from a current generator, a battery, batteries or any other source that can power electrical current receivers .

7. A container as in claim 1, characterized in that the distance between individual electrical conductors (6) and (7) of the generator of electromagnetic fields (16) and (17) does not exceed 5.00 mm.

8. A container as in claim 6, characterized in that the generator of the electromagnetic field (16) and/or (17), mounted on the outer surface of the inner wall (5) has an external impulse power supply with the rate of transmitting an electrical energy impulse from outside no longer than 1/50 sec, whereas the number of impulses does not exceed 20 per second, and the impulse itself is caught up by energy batteries installed inside the loading chamber of the container (1) .

9. A container as in claim 8, characterized in that the number of batteries installed range from 10 to 15.

10. A container as in claim 9, characterized in that the energy batteries installed inside the loading chamber of the container (1) release the received energy subsequently, one by one, so as to obtain, in the minimum drops, the "B" magnetic induction value that is necessary to maintain the broken gravitational bonds.

11. A container as in claim 6, characterized in that the generator of the electromagnetic field (17) has elements and soft ferromagnetic alloys, such as - among others - low-alloy steels, steel-silicon alloys, iron- nickel alloys and cobalt-nickel alloys .

12. A container as in claim 1, characterized in that it has an electromagnetic field generator (17) installed on the inner surface of the outer wall (4), and a magnetic field generator (18) installed on the outer surface of the inner wall (5) .

13. A container as in claim 1, characterized in that a magnetic field generator (18) is installed on the inner surface of the outer wall (4) and on the outer surface of the inner wall (5) of the container (1) .

14. A container as in claim 1, characterized in that the interior of the container (1) has devices to stabilize the load when there is no gravitation.

15. An antigravitational overcoat, characterized in that its elements are made of any elastic materials that are good electric current insulators and have no less than two elastic insulating coatings (13) , inside which there is at least one layer of electrical conductors (12) whose distance from one another ranges from 0 mm to 10.00 mm, while the antigravitational overcoat (11) is connected in an optional way, facilitating a free flow of electric current, with a base (14) which is optional in shape and has considerable stiffness and endurance, and which has two parallel bearing walls: a lower one (4) and an upper one (5) ; whereas between those walls and/or on the inner surface of the lower wall (4) and on the inner surface of the upper wall (5) or the base (14) there is an optional generator of monopolar magnetic fields (18) with the "B" electromagnetic induction, while the free space between the generator surface (16) and/or (17) and/or (18) installed on the inner surface of the outer wall (4) between the generator surface (16) and/or (17) and/or (18) installed on the inner surface of the upper wall (5) ranges from 0.1 mm to 20.00 mm.

16. An overcoat as in claim 15, characterized in that each of its constituent elements has, between two outer elastic and insulating coatings (13), two layers of electrical conductors (12) separated by an additional elastic coating that is an electric current insulator and which is permeable by an electromagnetic field.

17. An overcoat as in claim 15, characterized in that each of its elements has zippers, facilitating the connection of particular electrical conductors (12) which is durable and effective in every point, installed in each layer inside the overcoat (11) .

18. An overcoat as in claim 15, characterized in that the antigravitational overcoat (11) is the electromagnetic fields generator of the base (14) .

19. An overcoat as in claim 15, characterized in that the distance between particular electrical conductors (12) of the antigravitational overcoat (11) does not exceed 3.00 mm.

20. An overcoat as in claim 15, characterized in that the base (14) of the antigravitational overcoat (11) has devices to stabilize the load when there is no gravitation.

21. A container as in claim 1, characterized in that the antigravitational overcoat (11) is the generator of the electromagnetic fields.