NL8700869A - Environmental kinetic to electrical conversion using magnetic flux - energy from kinetic particles or photon field into electron current in conductor surrounding permanent magnet - Google Patents

Abstract

The energy conversion method uses a permanent magnet (11) which is installed in the space within a sec. coil (13) which lies within and concentric with a pref. superconducting prim. winding (12). The axis of magnetisation lies in a plane parallel to the upper and lower boundary planes of the coils (12, 13), which are accommodated between thermally conductive plants (14, 16) of e.g. Cu or Al with outwardly projecting ribs (15, 17) of the same material. Alternating current through the prim. coil (12) generates an alternating magnetic field at right angles to that of the magnet (11). The resultant field traverses the sec. coil (13) and induces a useful voltage in it. Energy drawn from the sec. coil (13) is replaced by heat transfer from the surroundings through the plates (14, 16) and ribs (15, 17) on either side of the structure.

Description

-1- VO 9111

Device for converting magnetic energy into electrical energy.

The invention relates to a device for converting magnetic energy into electrical energy, comprising an electric conductor in which an electromotive force can be generated by magnetic induction, and arranged to keep said conductor in the field of a permanent magnet and comprising a electrical conductor adapted to carry an electric current therethrough.

Such devices are known, e.g. from the 10 physics manuals. These manuals explain how an electromotive force is generated by moving a magnetic field relative to a conductor in that conductor, as well as how a magnetic field is created by an electric current carried by a conductor.

The devices described in the manuals serve only to explain the occurring phenomena. There has hitherto been no usable converter in which magnetic energy is converted into electrical energy with some efficiency.

The object of the invention is to provide a useful converter of the type described. This object is achieved according to the invention with a device in which the electrical conductor or conductors is or are arranged such that the conductor arranged to carry an electric current therethrough creates in operation a magnetic field which together with the field of the permanent magnet provides a variable resulting field so that said electromotive force is generated in the former electrical conductor.

In the device according to the invention a changing magnetic field is formed by a changing current jR-ft «* -2- fed into an electrical conductor. The resultant of this changing field and the field of a permanent magnet is thus also subject to change. Due to this changing resulting field, an electromotive force is induced in an electrical conductor 5. By suitable choice of the arrangement of electrical conductor (s) and permanent magnet, the greatest possible electromotive force is aimed for. The permanent magnet whose field is used in the device according to the invention does not necessarily have to be part of the device. Optionally, e.g. the earth's magnetic field can be used.

In a suitable embodiment of the device according to the invention, the electric conductors are two concentric coils arranged substantially in a plane within each other and the permanent magnetic field is provided by a permanent magnet which is arranged in said plane within the interior of the two coils. the magnet axis of the magnet is directed substantially in said plane.

In this embodiment, passing an alternating current through one of the two coils creates an alternating magnetic field. The result of this alternating field and the permanent field is an alternating field, the vector of which always passes the turns of the second coil. Thus, an electromotive force is optimally induced in the second coil. The magnetic flux variation in the first coil in this way causes a much greater flux variation in the second coil. The power delivered by the second coil is thus greater than the power input to the primary coil. The additional energy required for this greater power is supplied by the environment of the system in the form of heat. Preferably, therefore, in the present embodiment of the device according to the invention, the magnet with the coils is held between two metal plates, provided with ribs erected transversely thereon for supplying heat to the system ** V- -3- of permanent magnet and flush.

In another suitable embodiment of the device according to the invention, the permanent magnetic field is provided by a cylindrical magnet and the electrical conductors consist of three coils arranged substantially symmetrically around the cylindrical magnet, of which coils the axes are directed towards the center of the cylindrical magnet and lie in a plane parallel to the major surfaces of the cylindrical magnet, while the coils are arranged to be coupled to a three-phase power source, so that in operation a magnetic rotating field or swing field is generated, which moves around the axis of the cylindrical magnet, while the conductor in which the electromotive force is generated consists of at least one flat plate, which is arranged substantially parallel to the cylindrical magnet and is provided with a connection point almost in the middle of the plate, which center is located in the axis of the cylindrical magnet, and from a connection point near the edge of the plate. The manner in which this embodiment of the device according to the invention works is comparable to the operation of the Faropolay homopolar generator. In this embodiment, the flat plate preferably forms part of a box-shaped body, in which the cylindrical magnet surrounded by an electrically insulating layer is received. This embodiment can also suitably be provided with e.g. metal plate connected to the magnet provided with upright ribs to be able to supply heat to the device.

In yet another embodiment of the device 30 according to the invention, the electrical conductors, as in the first embodiment discussed above, are two concentric coils arranged substantially flush with one another. Unlike in the first embodiment, however, the permanent magnetic field is provided by two permanent permanent arrays disposed on either side of said plane; (-4-4 magnets directed opposite to each other in a direction perpendicular to said plane along or almost along the axis of the concentric coils. In operation, one of the coils is supplied with an alternating current. magnetic field is alternately amplified by the field of each of the permanent magnets, thus, in the second coil, an electromotive force is induced in a similar manner as if a permanent magnet is alternately introduced into the space within the coil and removed therefrom. coils and two permanent magnets preferably held in a support structure which is provided on either side near each of the permanent magnets with a system of metal plate with ribs erected transversely thereon for supplying heat to the device.

Although only a few embodiments of the device according to the invention have been discussed above, it will be clear that many variants can be realized. It is always important that a resulting changing magnetic field is created by composing a permanent magnetic field with an alternating magnetic field and that the resulting alternating magnetic field is optimally utilized to induce an electromotive force in an electrical conductor.

The invention is further elucidated with reference to the drawing, in which: fig. 1 is a side view of an embodiment of the device according to the invention; Fig. 2 shows a section along the line II-II through the device according to Fig. 1; Fig. 3 is a similar section along line III-III; Figures 4A and B are schematic representations of the magnetic fields in operation in the device according to Figure 1; Fig. 5 shows a vector diagram of the occurring energies i-«-5-; Fig. 6 is a top plan view of another embodiment of the device according to the invention; Fig. 7 shows a section along the line VII-VII through the device according to Fig. 6; Fig. 8 is a schematic side view of yet another embodiment of the device according to the invention; Fig. 9 shows a section along line IX-IX through the device according to Fig. 8; Fig. 10 shows a similar section along line X-X; FIG. 11 is a schematic representation of the course of the magnetic field lines in the device of FIG. 8 at a given time; and FIG. 12 is a similar representation at a subsequent time when the alternating current through the primary coil is just reversed.

20 In Figs. 1-3 show a first embodiment of the device according to the invention. In this embodiment, a permanent magnet 11 is disposed in the space that remains open within a secondary coil 13, which itself is arranged concentric with and within a primary coil 12. The leads of the coils 12 and 13 are not shown in the figures shown. The magnet 11 is arranged within the array of coils 12 and 13 such that the magnet axis is in a plane parallel to the planes delimiting the coils at the top and bottom.

The system of permanent magnet 11 and coils 12 and 13 is interposed between two plates 14 and 16 of a suitable heat-conducting material, which plates are provided with ribs 15 (on plate 14) and 17 (on plate 16) perpendicular thereto. Plates and ribs can e.g. consist of copper or aluminum.

If in operation an alternating current is passed through the primary r 4 -6 coil 12, as shown in Figs. 4A and 4B, an alternating magnetic field will be created. The field of the permanent magnet 11 is indicated in the figure by Np-Sp. The result of both magnetic fields is an alternating magnetic field Nr-Sr. A voltage is induced in the secondary coil 13 by this resulting alternating field.

Fig. 5 shows a vector diagram of the energies involved. The vector AB represents the energy of the permanent magnet, the vector BC is the energy supplied through the primary coil and the vector CA is the energy potentially extractable from the secondary coil. Since this energy to be extracted is greater than the energy supplied via the primary coil, energy in the form of heat will be extracted from the environment via the permanent magnet 11. A permanent supply of heat is therefore required, which is achieved by the set of ribbed plates on either side of the coil and magnet system.

In Figs. 6 and 7 are resp. a top view and a cross-section of another embodiment of the device according to the invention. In this embodiment, a cylindrical magnet 21 surrounded by a suitable insulation 22 is received in a box-shaped body 23 of a suitable electrically conductive material, e.g. of copper. The box 23 is essentially formed by two parallel plates or discs, which are joined together by a strip-shaped ring. The plate, which forms the top surface of the box 23, is provided with a pole 24 in the center and is provided with another pole 25 along the edge.

An annular body 26 is arranged around the box 23 at some distance therefrom. Three coils 28 are arranged symmetrically around the ring 26 on suitable projections 27. The coils 28 are connected to a three-phase generator in a manner not shown. In operation, the coils are thus energized successively, so that a rotating magnetic flux is obtained, as a result of * -7- the flux generated in the coils and the flux of the permanent magnet. The rotation of the magnetic flux results in the copper box 23. an electric potential, according to the same principle as that of the Faropolay homopolar generator 5. The electrical energy thus generated is extracted on the one hand from the three-phase generator which energizes the coils, on the other hand from the environment, so that cooling occurs. In order to supply the necessary heat, the box 23 is therefore connected via an electrically insulating intermediate layer 29 to a disc 30 of suitable material, e.g. aluminum, provided with cooling fins or rather heat supply fins 31.

In Figs. 8-10 show in side view and in cross-section yet another embodiment of the device according to the invention. In this embodiment, in a suitable support structure 32, two concentrically arranged coils 33 and 34 are held, of which coils the connecting wires are not shown. Above and below the plane of the coils, two permanent magnets 35 and 36 facing each other are arranged in the support structure 20 32. The magnet axes almost or completely coincide with each other and with the axis of the coils 33 and 34. By facing each other here is meant that either the north pole of each of the magnets is on the side of the magnet facing the coils, or the south pole.

On either side of the support structure 32 it is connected to a heat supply system consisting of a metal plate 37, respectively. 38, on which raised the ribs 39, respectively. 40.

30 In Figs. 11 and 12, the device according to Fig. 8 is shown schematically. Also in those figures the course of the magnetic field lines is indicated at two successive moments of passage of an alternating current through the primary coil 33. At the first moment (fig. 11), that current 35 has a certain direction, so that a magnetic field is created with as it was a north pole below the plane of the coils.

it. ** -, ·. r- i -8-

This field is amplified by the magnet 35 above the coils and "counteracted" by the magnet 36. The next moment (Fig. 12) the direction of the current through the primary coil 33 is reversed and a magnetic field is created with, as it were, a south pole below the plane of the coils.

This field is just opposite to the field at the previous moment. It is amplified by the magnet 36 under the coils and "counteracted" by the magnet 35. The effect of these fields thus formed on the secondary coil 34 is the same as when a permanent magnet is alternately inserted into and removed from the coil 34. An electromotive force is induced in the coil 34. The power to be delivered by the secondary coil is greater than the power consumed by the coil 33 due to the amplifying influence of the permanent magnets.

The difference is extracted from the environment in the form of heat via the heat supply construction.

Claims (7)

Device for converting magnetic energy into electric energy, comprising an electric conductor in which an electromotive force can be generated by magnetic induction, and arranged to keep said conductor 5 in the field of a permanent magnet, and comprising an electric conductor which is adapted to carry an electric current therethrough, characterized in that the electric conductor or conductors is or are arranged such that the conductor arranged to carry an electric current therethrough creates a magnetic field which, together with the field of the permanent magnet provides a variable resulting field so that said electromotive force is generated in the former electrical conductor. 2. Device according to claim 1, characterized in that the electrical conductors are two concentric coils arranged substantially in a plane within each other and in that the permanent magnetic field is provided by a permanent magnet which in said plane within the inner 20 of the two coils is arranged with the magnet axis of the magnet directed substantially in said plane. 3. Device as claimed in claim 2, characterized in that the magnet with the coils is held between two metal plates provided with ribs 25 arranged transversely thereon for supplying heat to the system of permanent magnet and coils. 4. Device as claimed in claim 1, characterized in that the permanent magnetic field is provided by a cylindrical magnet and that the electrical conductors consist of three coils arranged substantially symmetrically around the cylindrical magnet, of which coils the axes are directed towards center of the cylindrical magnet and are in a plane parallel to the major surfaces of the cylindrical magnet, while the coils f - - '* - -10- are arranged to be coupled to a three-phase power source, so that in operation a magnetic rotating field or rocking field is generated, which moves around the axis of the cylindrical magnet, while the conductor in which the electromotive force is generated consists of at least one flat plate, which is arranged substantially parallel to the cylindrical magnet and is provided with a connection point substantially in the center of the plate, which center is in the axis of the cylindrical magnet, 10 and from a connection point near the edge of the plate. Device as claimed in claim 4, characterized in that the flat plate forms part of a box-shaped body in which the cylindrical magnet, surrounded by an electrically insulating layer, is received. 6. Device according to claim 1, characterized in that the electric conductors are two concentric coils arranged substantially in a plane within each other and in that the permanent magnetic field is provided by two permanent magnets arranged on either side of said plane, which are opposite to each other are spaced from each other in a direction perpendicular to said plane along or substantially along the axis of the concentric coils. 7. Device as claimed in claim 6, characterized in that the coils and the two permanent magnets are held in a supporting construction which is provided on either side near each of the permanent magnets with a system of metal plate with ribs erected transversely thereon for supplying heat to the facility. ψ