WO2021211082A1 - A magnetic field routing and electric generation system - Google Patents

Abstract

The present invention relates to a system (1), comprising at least one magnetic flux source (2), at least one coil (3), at least one magnetic flux routing element (4) positioned between the magnetic flux source (2) and the coil (3) wherein the magnetic flux source (2) and the coil's (3) positions are fixed relative to each other; moving manually or automatically, with the help of its motion inducing electricity on the coil (3) by changing the power and/or density and/or amount of the magnetic flux to which the coil (3) is exposed and/or changing the angle between magnetic flux lines and the coil (3).

Description

A MAGNETIC FLUX ROUTING AND ELECTRIC GENERATION SYSTEM

TECHNICAL FIELD

The present invention relates to a system that enables the generation of electricity by using the principle that the magnetic flux moves over the path with the highest magnetic flux conductivity.

BACKGROUND OF THE INVENTION

Electricity generation by induction is generally a physical method, and alternating current is generated by using an electrical conductor. In the said method, a coil is induced with the help of a magnetic field. The number of magnetic field lines passing through a field constitutes the magnetic flux. Induction current is the current obtained by using a magnet or magnetic field without using a generator.

The induction and electricity generation tools used today are devices that generate electricity by moving a conductive wire in a magnetic field or by moving a magnetic field around a conductive wire by using mechanical force. In such devices, brushes should be used in general. Also, the efficiency of these devices decreases due to large masses of coils and magnetic flux sources.

In the patent document numbered CN202167976, a power supply with a magnetic field changing switch in the form of a button, which is a magnetic field changing system, is mentioned. The power supply includes a magnetic field switching system and this system includes a magnetic mechanism. The magnetic mechanism has at least two magnets. At least one magnet is mobile and a permanent magnet is relatively fixed. Also, there is an inductive coil in the system. The moving magnet is activated by a drive system and this drive system is controlled with the help of a button. Since the inductive coil is positioned in the magnetic field, electrical energy is obtained inductively by changing the magnetic field. In the patent document numbered EP1160958A2, another patent document in the literature, a magnetic field interruption electric generator and a method for generating electricity is mentioned. In the invention disclosed in the said document, the electric generator comprises an inductor, an inductive coil located around a ferromagnetic core, and an inductive coil and a mobile magnetic field interruption element positioned near the inductor. In the generator, an electric field is created by the inductor, the magnetic field changes in the inductive coil as a result of the movement of the magnetic field interrupting element, and thus, electric current is generated on the inductive coil.

As can be seen from the documents above, in the systems in the prior art, the coil is fixed and the magnetic flux source is mobile, there is no system in which the coil and the magnetic flux source are fixed relative to each other, and these systems cannot provide an effective energy generation.

BRIEF DESCRIPTION OF THE INVENTION

The object of the present invention is to produce electricity as a result of moving the magnetic flux routing element by using mechanical force thereby changing the power and/or density and/or amount of the magnetic flux which the coil (or coils) are exposed to, and/or changing the angle between magnetic flux and the coil (or coils)

Another object of the invention is to develop a magnetic flux routing and electricity generation system with low production costs.

Another object of the invention is to develop a magnetic flux routing and electricity generation system that allows the use of larger coil (or coils) and a stronger magnetic flux source (or sources) than existing electricity generation systems which does not require the use of brushes.

Yet another object of the present invention is to develop a magnetic flux routing and electricity generation system with the help of increasing the number of sections of the magnetic flux routing element with different magnetic flux conductivity that enables to increase the number of changes in the magnetic flux which the coil (or coils) exposed to per turn of magnetic flux routing element thus achieving higher efficiency. DETAILED DESCRIPTION OF THE INVENTION

To achieve the objects of the invention, "A Magnetic Flux Routing and Electricity Generation System" according to the invention is illustrated in the attached drawings, in which;

Figure 1. is an exemplary view of the system developed with the invention.

Figure 2 is an exemplary view of the positioning of more than one coil, magnetic flux routing element, more than one magnetic flux source, magnetic circuit connector, inner stabilizer, and rotor in the system developed with the invention.

Figure 3 is an exemplary view of more than one coil in the system developed with the invention.

Figure 4. An exemplary view of the magnetic flux routing element and rotor in the system developed with the invention. Figure 5. An exemplary view of the magnetic flux source in the system developed with the invention.

Figure 6. An exemplary view of the magnetic circuit connector in the system developed with the invention.

Figure 7. An exemplary view of the inner and outer stabilizer in the system developed with the invention.

Figure 8. An exemplary view of the magnetic flux routing element, inner stabilizer, outer stabilizer (half of the exemplary view shown in the figure), and the rotor in the system developed with the invention.

Figure 9. An exemplary view of the positioning of more than one coil, magnetic flux routing element, more than one magnetic flux source, magnetic circuit connector, and rotor in the system developed with the invention.

Figure 10. An exemplary view of the positioning of more than one coil, magnetic flux routing element, rotor, and magnetic circuit connector, which is also used as a magnetic flux source in an alternative application of the system developed with the invention. Figure 11. An exemplary view of the positioning of more than one coil, magnetic flux routing element, more than one magnetic flux source, magnetic circuit connector, inner stabilizer, and rotors in an alternative application of the system developed with the invention.

Figure 12. Another exemplary view of the positioning of more than one coil, magnetic flux routing element, more than one magnetic flux source, magnetic circuit connector, inner stabilizer, and rotors in an alternative application of the system developed with the invention.

Figure 13. An exemplary view of the rotor in the system developed with the invention.

Figure 14. An exemplary view of the magnetic flux routing element produced by shaping material with high magnetic flux permeability in an alternative application of the system developed with the invention. Figure 15. An exemplary view of the magnetic flux routing element produced by shaping material with low magnetic flux permeability in an alternative application of the system developed with the invention.

All the parts illustrated in figures are individually assigned a reference numeral and the corresponding terms of these numbers are listed as follows: 1. System

2. Magnetic flux source

3. Coil

3.1 Separator

4. Magnetic flux routing element 4.1 First part

4.2 Second part

5. Outer stabilizer 5.1 Inner stabilizer

6. Rotor 7. Magnetic circuit connector

7.1 Main or secondary magnetic flux source

Magnetic flux routing and electricity generation system (1) developed with the present invention comprises, at least one magnetic flux source (2), at least one coil (3), at least one magnetic flux routing element (4), which is positioned between the magnetic flux source (2) and the coil (3), the magnetic flux source (2) and the coil (3) positions are fixed relative to each other,

• moves manually or automatically,

• by the help of its movement, induces electricity on the coil (3) by changing the power and/or density and/or amount of the magnetic flux which the coil (3) is exposed to, and/or changing the angle between magnetic flux lines and the coil (3)

• produced by shaping a material or shaping the assembled materials with different magnetic flux permeability,

• comprises at least a first part (4.1) and at least one second part (4.2) whose magnetic flux permeability is different from each other.

The magnetic flux routing element (4) according to the invention comprises at least a first part (4.1) and at least one second part (4.2) produced by shaping a material or shaping combined materials, whose magnetic flux permeability is different from each other. Said magnetic flux routing element (4) preferably has a structure in the form of a propeller, a rotating band, a disk, a cylinder, or a hollow cylinder. The magnetic flux routing element (4) forms heterogeneous regions in terms of magnetic flux permeability within the volume covered by the movement of the magnetic flux routing element (4) since it contains at least one first part (4.1) and at least one second part (4.2) with different magnetic flux permeability. Thus, magnetic flux routing element's (4) motion induces electricity on the coil (3) by changing the power and/or density and/or amount of the magnetic flux which the coil (3) is exposed to, and/or changing the angle between magnetic flux lines and the coil (3).

In a preferred embodiment of the invention,

• if the magnetic flux routing element (4) is produced by shaping combined materials, the first part (4.1) is made of materials with low magnetic flux permeability such as bismuth, a magnet with arranged polarity, air, vacuum, pyrolytic carbon, superconductors, and the second part (4.2) is made of materials with high magnetic flux permeability such as iron, nickel, nickel, and iron-containing alloys, a magnet with arranged polarity, mumetal, nanoperm, permalloy metglas.

• if the magnetic flux routing element (4) is produced by shaping only one material, the difference in magnetic flux permeability of the first part(4.1) and the second part (4.2) is obtained by using magnetic shielding methods or by making use of the magnetic flux permeability difference of the medium used and the magnetic flux routing element (4)

In the system (1) according to the invention, the magnetic field lines are directed to and concentrated in the regions behind (relative to the north pole of the magnetic flux source, between the first part (4.1) and the second part (4.2)) the second parts (4.2) and in regions behind (relative to the north pole of the magnetic flux source) the first parts (4.1), the intensity of the magnetic field lines is reduced. Thus, the density of the magnetic field lines is higher in the regions behind (relative to the north pole of the magnetic flux source) the second parts (4.2) of the magnetic flux routing element (4), which have relatively high magnetic flux permeability, compared to the regions behind the first parts (4.1) with relatively low magnetic flux permeability.

In an embodiment of the present invention, the system (1) comprises at least one inner stabilizer (5.1) which is made of a material with low magnetic flux conductivity and carries the coil (3) and the magnetic flux routing element (4) and prevents the magnetic flux from reaching the outside of the system (1). The inner stabilizer (5.1) has a structure that does not prevent the movement of the magnetic flux routing element (4). The system (1), can also comprises at least one outer stabilizer (5) positioned to accommodate the inner stabilizer (5.1) coil (3), magnetic flux routing element (4), and rotor (6). If the number of coils (3) is more than one, the system (1) according to the present invention preferably comprises separators (3.1) made of material with low magnetic flux permeability to separate the coils (3) from each other

In a preferred embodiment of the invention, the system (1) comprises cores made of material with high magnetic flux permeability inside coils (3).

In an another preferred embodiment of the invention, the system (1) comprises at least one rotor (6) that moves the magnetic flux routing element (4). The magnetic flux routing element (4) is moved by the power provided by the rotor (6).

In another preferred embodiment of the invention, the system (1) includes more than one magnetic flux routing element (4) positioned inside the outer stabilizer (5).

In another preferred embodiment of the invention, at least one magnetic circuit connector (7) can be used as a main or secondary magnetic flux source (7.1) by positioning at least one magnetic flux source (2) on at least one magnetic circuit connector (7).

In the system (1) developed with the invention, when the power is transmitted through the rotor (6), as a result of the circular movement of the magnetic flux routing element (4), first parts (4.1) and second parts (4.2) move and the same coil (3) periodically remains behind first part (4.1) and second part (4.2) thus magnetic flux routing element’s (4) motion induces electricity on the coil (3) by changing the power and/or density and/or amount of the magnetic flux that the coil (3) is exposed and/or changing the angle between magnetic flux lines and the coil (3).

When the power is not transmitted to the system (1), most of the magnetic field lines emerging from the north poles of the magnetic flux sources (2), pass through second parts (4.2) of the magnetic flux routing element (4) which have high magnetic flux permeability and it completes the magnetic circuit by passing through the coils (3) behind (according to the north pole of the magnetic flux source) second parts (4.2). A smaller number of magnetic field lines pass through the first parts (4.1) of the magnetic flux routing element (4) which have relatively lower magnetic flux permeability and the coils (3) behind (according to the north pole of the magnetic flux source) first parts (4.1). In the system (1) developed by the invention, the coil (3) is induced by the rotation of the magnetic flux routing element (4). As a result of continuous rotational motion, a periodic, variable current will be induced on the coil (3) and an alternating current is obtained thanks to the variable magnetic field. The induced current can be transmitted via a conductive line to be used or stored.

As a result of the design of the system (1) according to the invention, the use of brushes is not required because the magnetic flux source (2) and the coil (3) remain fixed relative to each other and only the magnetic flux routing element (4) moves and thus production/maintenance costs are reduced. Also, larger coils (3) and stronger magnetic flux sources (2) can be used. Also, in case of first parts (4.1 ) and second parts (4.2) are in the form of a propeller, rotating band, disc, or cylinder, the number of first parts (4.1) and second parts (4.2) of the magnetic flux routing element (4) can be increased and thereby higher efficiency can be obtained by increasing the number of magnetic flux changes on the coil (3) per unit time.

Claims

1. A magnetic flux routing and electricity generation system (1) which comprises at least one magnetic flux source (2) and at least one coil (3), providing electricity generation by inducing the coil (3), characterized in that; the magnetic flux source (2) and the coil (3) being in fixed positions relative to each other, and comprising; at least one magnetic flux routing element (4) located between the magnetic flux source (2) and the coil (3), whose positions are fixed relative to each other, moving manually or automatically, inducing electricity on the coil (3) by changing the power and/or density and/or amount of the magnetic flux to which the coil (3) is exposed and/or changing the angle between magnetic flux lines and the coil (3) with the help of its movement, produced by shaping a material or shaping the assembled materials with different magnetic flux permeability, comprising at least one first part (4.1) and at least one second part (4.2) whose magnetic flux permeability are different from each other.

2. A system (1 ) according to Claim 1 , characterized in that in case of the magnetic flux routing element (4) is produced by shaping combined materials, the first part (4.1) is made of materials with low magnetic flux permeability such as bismuth, a magnet with arranged polarity, air, vacuum, pyrolytic carbon, superconductors and the second part (4.2) is made of materials with high magnetic flux permeability such as iron, nickel, nickel, and iron- containing alloys, magnet with arranged polarity, mumetal, nanoperm, permalloy metglas.

3. A system (1) according to Claim 1, characterized in that in case of the magnetic flux routing element (4) is produced by shaping only one material, the difference in magnetic flux permeability of the first part(4.1) and the second part (4.2) is obtained by using magnetic shielding methods or by making use of the magnetic flux permeability difference of the medium used and the magnetic flux routing element (4).

4. A system (1) according to any of the preceding claims, characterized in that the magnetic flux routing element (4) has the shape of a propeller, rotating band, disc, cylinder, or hollow cylinder.

5. A system (1) according to any of the preceding claims, characterized in that the system (1) comprises at least one inner stabilizer (5.1) which is made of a material with low magnetic flux conductivity and carries the coil (3) and the magnetic flux routing element (4) and prevents the magnetic flux from reaching the outside of the system (1).

6. A system (1) according to claim 5, characterized m that the inner stabilizer (5.1) is in a structure that does not prevent the movement of the magnetic flux routing element (4).

7. A system (1) according to claim 5, characterized in that the system (1) comprises at least one outer stabilizer (5) positioned to accommodate the inner stabilizer (5.1), the coil (3), the magnetic flux routing element (4), and the rotor (6).

8. A system according to claim 5, characterized in that the system (1) comprises at least one magnetic flux routing element (4) positioned inside the outer stabilizer (5).

9. A system (1) according to any of the preceding claims, characterized in that in case the number of coils (3) is more than one, to separate the coils (3) from each other, the system (1) comprises separators (3.1) made of material with low magnetic flux permeability .

10. A system (1) according to any of the preceding claims, characterized in that the system (1) comprises cores made of material with high magnetic flux permeability inside coils (3).

11. A system (1) according to any of the preceding claims, characterized in that, the system (1) comprises at least one rotor (6) that moves the magnetic flux routing element (4).

12. A system (1) according to any of the preceding claims, characterized in that , the system (1) comprises at least one magnetic circuit connector (7) connecting north and south poles of magnetic flux source(s) (2) to minimize the air gap in magnetic circuit and thus increasing the efficiency of the system (1).

13. A system according to claim 11, characterized in that , at least one magnetic circuit connector (7) can be used as a main or secondary magnetic flux source (7.1) by positioning at least one magnetic flux source (2) on at least one magnetic circuit connector (7).