DE19852470A1 - System for generating electrical energy operates a support rail over a coil guided at both ends into two bearings, and three permanent magnets on the rail with alternating polarity as well as springs fastened on both the rail's ends. - Google Patents

Abstract

A coil core (SP) has an induction coil (IS) and clamps (K1,K2) for it. This core is designed with poles (Sp1,Sp2) as a U-core. Over the coil core is a support rail (TS) guided at both ends into two bearings (L1,L2). On this rail are three permanent magnets (DM1,DM2,DM3) with alternating polarity (N,S,N/S,N,S). Springs (F1,F2) are fastened on both the rail's ends (FS1,FS2) which are reached if any pair of the magnets opposes the poles.

Description

The invention relates to electrical power generation system using electromagnetic induction by means of magnets and induction coils with a core. Such energy generation systems are of various types known and form, mainly in the form of Synchronous generators are the basis of current generation electrical energy.

These electric generators have a magnet wheel on which at least one magnet with its two poles radially attached is brought; the pole wheel is surrounded concentrically by the stator with induction coils with iron core.

By rotating the magnet wheel, driven by z. B. Steam door bines or hydropower turbines, one at the terminals the induction coils generates measurable AC voltage, de ren frequency from the product of the number of pole pairs p and the Speed n of the rotating magnet wheel results. As magnets Electromagnets are used almost without exception. This form of electrical energy generation is based on the today mainly operated as thermal power plants Power generation systems on conversion exhaust themselves of raw materials such as coal and oil as well as radioactive materials lien.

In addition, these energy sources are subject to increasing the critical consideration from an environmental perspective.  

The object of the present invention is one possibility to demonstrate the generation of electrical energy without or at least with a minimal proportion of such exhaustive primary energies, and under Application of the electromagnetic induction law by means of magnets, in particular permanent magnets and Induction coils with core.

To solve this problem, the The present invention proposed that the magnetic Field change by changing the relative location of the Poles of magnets and the poles of the core of Induk tion coils in a mechanical resonant circuit.

Compared to conventional energy producers, this has System the advantage that the magnetic force effect between the magnets and the coil core Energy generation in addition to the induction effect is used, and from tried and tested technical concepts Can be used.

According to an advantageous embodiment of the invention provided that the magnets are permanent magnets. Through this The measure does not account for the energy balance Electrical energy used to excite electromagnets should be spent. Permanent magnets with the required retentivity and high coercive field strengths more recently available.  

To design the mechanical spring resonant circuits cheaply too it is advantageous that according to claim 3 Induction coils are fixed with the core stationary, and the Magnets are part of the spring resonant circuit. This means that the considerably higher mass of induction coils with core is arranged at rest.

An advantageous constructive implementation is the subject of Claim 4.

To regarding the level of tension and energy quantity a simple increase of the achieved in a system Training in accordance with Claim 5 proposed.

The achievable advantages of such an arrangement can be already by counting the systematically required function elements such as springs, magnets and coil cores lichen.

To those caused by the forces of attraction mechanical loads in the bearings of the mounting rail will minimize an electrical power generation system proposed according to claim 6.

In terms of spatial concentration, it can be considered be considered advantageous, an arrangement according to patent to provide claim 8.

Further details and advantages of the invention can be found in the following description of the exemplary embodiments shown in FIGS. 1 to 4.

Fig. 1 shows a schematic diagram with the required functional elements of the invention.

Fig. 2 shows the realization of a multiplying power generation assembly.

Fig. 3 shows an arrangement with mirror images arranged induction coils.

In Fig. 1 it can be seen the spool core Sp with the induction coil IC and the terminals of K 1 and K 2. The coil core is constructed as a U-shaped core with the poles Sp 1 and Sp 2 in the drawing above the coil core, the supporting rail TS is , which is guided at both ends in two bearings, schematically indicated by L 1 and L 2. On the mounting rail TS three magnets, preferably permanent magnets, DM 1, DM 2 and DM 3 are attached, with alternating polarity N, S, N (as shown) or SNS. These magnets are mounted on the mounting rail at a mutual distance a that corresponds to the center distance of the two legs of the coil core Sp. The springs F 1 and F 2 are attached to the two ends FS 1 and FS 2 of the mounting rail TS. Furthermore, a connector AN is shown on the mounting rail, on which a drive element, which is not shown, engages in such a way that the mounting rail TS can be moved back and forth in the direction of its longitudinal axis LA. The two end positions of the mounting rail TS are each reached when a pair of magnets DM 1, DM 2 or DM 2, DM 3 the two poles SP 1 u. SP 2 of the coil core Sp faces. The two springs F 1 and F 2 are attached with their respective second ends to a fixed bearing ML. In the two end positions one of the two springs F 1 or F 2 is tensioned and the other one is tensioned. There is an air gap Ls between the magnets and the poles of the coil core. In the state shown in FIG. 1, the first magnetic circuit runs from the magnet DM 1 with its north pole N via the air gap Ls, the pole Sp 1 of the coil core Sp to the pole Sp 2 of the coil core Sp, in turn via the air gap to the south pole S of the magnet DM 2 and over the support rail TS back to the magnet DM 1. In the rest position, the magnetic flux Ø is constant in the state 1 shown, and between the terminals K 1 and K 2 of the induction coil IS the voltage U = O is measured. When the support rail TS moves in the direction of the spring F 2, the magnetic flux Ø is reversed up to the second end position, and according to the law of induction Uo = - d Ø / dt the voltage Uo is measurable at the terminals. When trying to carry out the above-described movement of the mounting rail TS with the magnets, it is found that the magnetic force in the magnetic circuits also counteracts a shift in the magnetic circuits described above. This is where the invention begins.

Depending on whether in the system shown tension or compression springs are used, one of the two springs F 1 or F 2, e.g. B. F 1 biased as a compression spring so that the Magnetic force just enough, the state shown N / Sp 1 and S / Sp 2. Attack now point to an external force F 3 in the direction of the second Zu stood S / Sp 1 and N / Sp 2, then this change of position possible with a small amount of force F 3. Because at the motion not only changes the magnetic flux, therefore  follow the electrical voltage Uo is generated, but also the magnetic forces correspond to the new magnetic circuit reverse now becomes when reaching the second Zu stood the spring F 2 tensioned and the spring F 1 relaxed.

By appropriate dimensioning of the forces involved, So the magnetic forces and the spring forces, the Minimize force F 3 so that essentially only the difference between spring force and magnetic force (see above) and the damping losses must be compensated.

The arrangement thus described represents a mechanical one Resonant circuit, its operation according to the requirement for the smallest possible, to be applied from the outside Energy is operated close to the resonance frequency. This Operating frequency is also in accordance with the In production law a determining factor for the electrical Order values.

In Fig. 1 a certain operating position is shown, the horizontal position; by appropriate dimensioning, it is easy to see, it is also possible to set up a vertical operation; another arrangement of the springs can also be provided.

So can be deviated from the linear arrangement shown in FIG. 1 in such a way that the induction coil IS or more induction coils with their coils cores and the permanent magnets DM are concentrically arranged in a known manner in the manner of a synchronous generator, in which the permanent magnets DM form the so-called pole wheel. This pole wheel will now oscillate around the common axis in accordance with an exemplary embodiment not shown, the springs of the mechanical resonant circuit being designed as torsion or spiral springs.

The processes in ferromagnetic materials (Weißsche Districts, Blochsche wall shifts, Barkhausen Effect, etc.) are extensive in the scientific literature explained and described. For technical purposes but only either induction or magnetic Power effect used.

From the above it is clear that according to the invention simultaneously and successfully the electro magnetic induction and the magnetic force effect electrical power generation while minimizing the leading energy can be exploited.

This can be achieved because the polarization of the coil core the folding of the Weiss districts next to the electrical ones Induction at the same time a force effect in motion direction of the permanent magnets. The mag net resonator an additional acceleration. This Growth in the form of kinetic energy is spring F 1 or F 2 added and there as poten cial energy. By a slight, too additional drive pulse F 3, this is buffered te potential energy released and to accelerate the Resonators used in the opposite direction.

The folding of the Weiss districts causes this Conception thus has a double effect: it creates immediately both electrical energy through induction as well Energy in the form of potential / kinetic energy through the Magnetic force.

The question of the demagnetization of the permanent magnets DM as The consequence of mutual induction effects is today magnets in compliance with the operating regulations negligible; see z. B. the company publication from Vacuumschmelze GmbH "Rare Earth Permanent Magnets Vacodym. Vacomax. "  

In FIG. 2, an arrangement is shown in which on the one hand the supporting rail TS with more than three in Fig. 1 shown magnet DM 1, DM 2 and DM 3 is provided as well as a plurality of induction coils IS 1. . . IS n are arranged on correspondingly formed coil cores. The remaining elements of the arrangement are not shown here.

Such an arrangement according to FIG. 2, it is possible to change the electrical characteristic by switching the coils IS 1 to IS 3, for. B. to change by series or parallel connection.

You can see that the number of magnets DM is one more than that Number of poles of the coil cores Sp.

Referring to FIG. 3, an arrangement is shown, the doubled voltage to Anord of FIG. 1 or 2 a having on the axis of the support rail mirrored structure. Recalled according to FIG. 1 operates, the magnetic force of the magnetic circuit as a compressive force on the L 1 and L 2, which inter alia results in friction losses.

By symmetrizing the magnetic forces in opposite magnetic circuits, these bearing loads can be reduced minimize. This arrangement is also space saving.

By appropriate use of z. B. three arrangements according to FIGS . 1 to 3 and their coordinated drive sequence of the systems, it is also possible to take a three-phase voltage.

The drive F 3 can - depending on the purpose fit - be trained very differently.  

If a motor is used, there is the possibility to excite several systems arranged in series according to FIG. 1, FIG. 2 or FIG. 3 in succession by a common shaft. If this is done with eccentrics offset by 120 ° (cams or crankshafts), the 3 phases R, S and T of a "linear three-phase alternator" are obtained. Since the required torque has to be provided in succession for each revolution and not simultaneously, this leads to minimization of the drive energy. Other examples include:

Used as an energy amplifier, a low power one AC motor draws its energy from the public grid (50 Hz) and amplifies it.

Used as an independent energy source, Low power engine - the z. B. at 3000 rpm. operated will - this task. The same applies to a direct current motor, which first drives its energy from a battery takes. Then replace them in the steady state Phases R and S the energy withdrawn. The third shoot Stromphase T is available for use.

Claims (8)

1. Electrical power generation system using the electromagnetic induction law by means of magnets and induction coils with a core, characterized in that the magnetic field change by changing the relative position of the poles (N, S) of magnets (DM) and the poles (Sp 1, Sp 2 ) of the core of induction coils (IS) in a mechanical resonant circuit. 2. Electrical power generation system according to claim 1, characterized, that the magnets (DM) are permanent magnets. 3. Electrical power generation system according to claim 2, characterized, that the induction coils (IS) are fixed with a core, and the magnets are part of a spring resonant circuit (F 1; F 2). 4. Electrical power generation system according to claim 3, characterized, that a movable in the direction of its longitudinal axis (LA) rail (TS) with their ends (FS 1; FS 2) each on one End of two springs (F 1; F 2) with the same one Longitudinal axis is attached, and the other ends of the  Springs are firmly clamped (ML) that on the mounting rail (TS) in the distance between the poles (Sp 1; Sp 2) of the coil core (Sp) at least three magnets (DM 1, DM 2, DM 3) alternating Polarity are attached so that the mounting rail (TS) is mounted so that the magnets (DM 1; DM 2; DM 3) each while maintaining an air gap (LS) alternating in pairs directly opposite the poles (column 1; Sp 2) of the coil core (Sp), and that each time one of the two springs (F 1; F 2) is under tension. 5. Electrical power generation system according to claim 4, characterized, that several induction coils (IS) on one multi-gift Leaving coil core (Sp) are arranged that the coils Core in the longitudinal direction in the same direction as the longitudinal axis the support rail (TS) expands and runs parallel to it, that the number of magnets (DM) is equal to the number of Coil core leg (Sp) plus one. 6. An electrical power generation system according to claim 4 or 5, characterized, that there are two identical arrays of induction coils (IS) with core mirrored to the longitudinal axis of the mounting rail (TS) face each other and each pole facing each other the poles of the coil cores (Sp) in each of the two end positions the mounting rail (TS) is opposite a magnetic pole (N, S). 7. The electrical power generation system according to claim 3, characterized,  that the induction coils (IS) with their cores as well as the Permanent magnets (DM) concentric in a manner known per se are arranged in the manner of a synchronous generator that the Permanent magnets (DM) form the pole wheel and around the common oscillate same axis, and that preferably as springs Torsion or coil springs are arranged. 8. Electrical power generation system according to one of the An sayings 3 to 7, characterized, that several systems are mechanically interconnected and be operated in chronological order that the Induk tion coils a multi-phase voltage is removable.