FR2626729A1 - Static electric generator with superconducting induction - Google Patents

Abstract

The subject of the invention is an alternating, static electric generator operating independently of any other external energy source. The invention consists in causing piezoelectric, ferroelectric or magnetostrictive elements 1 2 to interact in a set of resonant cavities for the purpose of determining through ultrasonic waves a variable polarisation of these elements and hence an electric current of high intensity. The exciter elements 1 are ultrasonic wave generators, the elements 2 are resonators and create an alternating current 3. The elements 1 vibrate under the effect of a voltage produced by an RLC oscillating circuit 8 9 1. The energy dissipation in the oscillating circuit is compensated by electromagnetic induction with the aid of superconducting coils 10 forming a primary winding and with the aid of ordinary auxiliary coils 11 forming a secondary winding. The superconducting coils 10 tap off a compensation current from the production current 3 with no Joule effect or any other impedance, hence with no energy alteration of this current. This type of lossless tapping with the aid of superconducting coils can be performed on any variable current and in particular on the oscillating circuit itself.

Description

 This invention relates to the field of electrical energy generators.

To date, no electric generator is really a creator of energy without the intervention of another source of energy which must be maintained or renewed.

 The object of this invention is the creation of a generator, static, alternative, independent of another source of energy.

 The invention consists in making piezoelectric, ferroelectric, or magnetostrictive elements interact in a set of resonant cavities, with the aim of generating powerful ultrasonic waves, determining a variable polarization of these elements, thus creating a high intensity alternating current. , and to use the superconductive properties of certain materials to limit and compensate, without loss, the induced energy dissipation. The superconductive device itself being capable of independently producing an electric current.

 When many crystalline substances are subjected to tensions or compressions along certain determined axes, an electric polarization is produced there. This is the case with certain anisotropic ionic crystals, such as quartz, barium titanate, lead zirconate, etc. This is the direct piezoelectric effect.

For quartz, by exerting a force Fx along a polar axis, one obtains at the pressure of 1 Atmosphere, or about 10 Newtons, an electric charge
Qx = 2.10 ## 7Coulomb / m2
With ceramics such as barium titanates or lead zircotitanates, we obtain charges 100 times higher, that is to say
Qx = 2 # a0-5 Coulomb / m2
By the phenomenon of resonance this result can be considerably amplified. In a liquid it can increase by at least a factor of 5, i.e. Qx = 2.10 5.5 = 1 10 Coulombs / m2
Conversely, when an electric field is applied to the opposite faces of one of these crystals, a variation in the dimensions of the crystal is observed, which depends on the voltage applied. It is the reverse piezoelectric effect.

 Certain ferroelectric crystals, such as TiO3Ba, also have the distinction of spontaneously polarizing. Their polarization can be reversed by applying a relatively weak electric field.

One of the devices leading to the proposed goal can be described, in a schematic, non-limiting manner, and by way of example, as follows
By placing TiO3Ba piezoelectric plates, face to face and side by side within an insulating fluid, according to FIG. 1, some (1) generating ultrasonic pulses by the effect of a voltage of some 3000 volts, the others (2) being piezoelectric resonators, a set of resonant cavities is formed, in which the vibrations of the plates, by mutually reinforcing, create ultrasonic waves of great power.

 An alternating polarization occurs on the resonator plates due to the pressure and depression of the ultrasonic acoustic waves.

Thin metallic reinforcements, having an excellent electrical and thermal conduction, are placed on these plates, where are collected induced, equal electrical charges and signs opposite to the polarization charges. In the external wires (3) connecting the reinforcements together, an electric current flows.

These plates all have elastic mechanical behavior. In the limits of elastic deformation, the movement is linear and obeys Hooke's law. The deformations are therefore proportional to the amplitude of the ultrasonic acoustic wave which strikes them. To vibrate at their natural frequency, in phase with the excitation frequency, the plates must have a thickness E = # = V (2N) -1
2 0 # being the wavelength in ceramic for the frequency N chosen, VO being the speed of sound in this same material, ie a thickness of the order of 25 mm for N = 100,000 Hz.

 By resonance phenomenon, the ultrasonic wave emitted by the excitation crystal (1) is echoed by the piezoelectric resonating crystal (2) and reinforces the next wave synchronously, and so on.

All the plates inducing each other, it follows a considerable increase in the amplitude of the oscillatory vibrations, determining in the receiving piezoelectric crystals (2), appreciable electric charges. For a pressure variation of 10 Atmospheres, i.e. a force close to 100 Newton / cm2, the previously calculated load becomes
Qx = 10-4.10 = 10-3 Coulomb / m2
The attenuation of the wave by absorption in the propagation medium as a function of the distance traveled is relatively low, since it only travels half a wavelength before being reinforced by the oscillation of the plate. opposite. In liquid, oil or water medium, for N = 100,000 Hz, the separation distance of the plates would be D = # = V (2N) -1, i.e. of the order
2 1 of 7 mm.

V1 being the speed of sound in the liquid considered.

 The thickness and the spacing of all the plates are calculated and adjusted in half-wave, according to the speed of propagation of the wave and its frequency, so that at resonance, all these plates vibrate in synchronization with an offset of half a wavelength.

The longitudinal vibration forces of a plate along the x axis, called the electrical axis, are also induced along the y axis, called the mechanical axis, L in the ratio Fy = - Fx (L = length, e = thickness), further increasing the am
e plitude of the oscillations and determining an increased polarization on the face x. The plates are connected to the frame (4) according to FIG. 1, or by any process limiting the damping constraints as much as possible, and by a material (5) of low acoustic impedance or by a layer of air, so as to avoid the rear radiation. The maximum power can thus be concentrated on the sides facing each other, parallel to the mechanical axis y
To increase the electrical charge Qx, the resonator plates consist of a stack of piezoelectric blades (7) of approximately 5mm thickness, in this example, and possibly # ferroelectric blades with spontaneous charge, of the electret type, separated by thin metal reinforcements.

These dielectric blades are oriented in the direction of their polarization, so that each metal frame is in contact on its two faces with two blades of the same polarity.

 This produces a battery of generator-capacitors delivering an alternating current, the power of which will vary according to the quality of the materials chosen, the number of elements, the frequency, the thickness and the surface area of the piezoelectric dielectrics.

With 400 resonator blades of 0.25 m2 and 5mm thick, formed in two rows of 200 plates, therefore with S = 100 m2, arranged and connected in parallel according to Figure 1, the previously determined load becomes:
Qx = 10 3 102 = 10 Coulombs For N = 100,000 Hz, the theoretical maximum intensity is i = 2QxN, that is
mi = 2.10-1.105 = 20,000 A, i.e. Ieff = 20,000. (# 2) -1 = 14,000 A
m
The capacity of the battery constituted by all of the generator-capacitor elements is: C = 10-9 (36 #) - 1. #. Se-1 = 2.10-4 Farads with # = 1130 for a type of TiO3Ba 2 2
S = 0.25 m. 400 = 100 m
e = 5 mmm The maximum voltage obtained is U = Qx = 10-1 = 500 volts, i.e. Veff = 350 V
m C
The theoretical maximum power is:: 2.10 eff
P = U. 1 = 10,000 Kva, i.e. Peff = 14,000 A. 350 V = 4,900 Kva
mmm
The excitation plates can be similar to the resonator plates or can be inspired by the model of the most efficient current transducers and in particular of the superconduction transducers. They also constitute capacitors whose thickness depends on the crystal used. They are interposed in order to obtain the best efficiency.

 The voltage and frequency of the excitation current (8) are supplied by an oscillating circuit RLC, constituted by a self-induction coil (9) and the capacitor of which is the set of piezoelectric excitation blades (1). This oscillating circuit is tuned to the natural resonance frequency of the receiving device constituted by the plates (2), therefore 100,000 Hz in this example. The oscillating circuit suitably adjusted is traversed by a current (8) intense and present at the terminals of the excitation blades, the high overvoltage sought.

 The inductor coil (9) of this oscillating circuit can be superconductive.

Its windings are then made of superconductive materials of the second kind preferably, stabilized son. This coil can thus withstand on the part of the magnetic field created, a relatively large self-induction with a minimum of losses by Joule effect, on condition of maintaining its operation below the critical values Tc, Jc, Hcl and Hc2, of the material used . The single inductor can be replaced by a set of several coils of less inductance, without mutual induction, in case of too high inductive magnetic field.

 The energy dissipated in the oscillating circuit, mainly by residual joule effect in the choke (8) or by dielectric losses in the capacitors (1), is compensated by taking from the production circuit (3).

This compensation sampling can be done by electromagnetic coupling of one or more superconductive coils (10) with one or more ordinary auxiliary coils (11), always in resonance with the oscillating circuit. The magnetic induction in the superconductive material of the windings and the intensity of the sampling current must remain below their critical values Ho and Ic, and the magnetic field of induction necessary can be important, depending on the dissipation of the oscillating circuit , it may be advisable to multiply the number of the superconductive sampling coils (10), rather than to increase their dimensions and therefore the effects. of superconductive samples (10), it is also advisable to limit the magnetic reaction effects of each by reducing the dimensions and therefore the effects, in favor of the number, in order to obtain the same results.

 The sampling coils (10) consisting of type 1 superconductive windings below Ho or type 2 below Hcl, have neither ohmic resistance to the current flowing through them, due to their superconduction, nor self-induction, nor self-reactance of the secondary windings (11), due to the expulsion of the magnetic induction by the Meissner effect, that is to say of its non-penetration in the superconductive windings.

 The sampling by electromagnetic coupling being done without heating of the primary winding (10), nor electromagnetic braking of the current which crosses it, is therefore carried out without significant losses. This type of induction sampling, without counterpart, without influence on a base current, using superconductive coils, can be carried out on any variable electric circuit. It can in particular be envisaged in the present description, to take the compensation current directly from the oscillating circuit, and even, by extension, to produce current from this oscillating circuit (8), by eliminating the ultrasonic transducer part. , according to the block diagram of Figure 3.

 The production of electrical energy by self-supply can thus be carried out from any rapidly varying electrical circuit, the coils (20) being superconductive, the coils (21) being ordinary and creating voltages or currents. It is thus possible, with batteries of superconductive coils, to create more energy than it is spent to establish and maintain the current of an oscillating circuit, or variable of any origin, the energy produced by induction resulting in no real borrowing from a basic current. When the superconductive coils (10) or (20) are intended to produce a fairly intense current and it is necessary to use a second type of superconductive material, the magnetic induction partially penetrates the material between Hcl and Hc2, creating a certain inductance in the windings. It is then necessary to have capacitors (15) in series with the windings, so as to cancel any Inductance, and therefore any impedance, for the chosen resonant frequency.

 Since superconducting can exhibit a relative allergy to alternating current at certain frequencies, each superconductive coil can be dissociated into two coils, which, using diodes for example, will only be crossed by a single alternation of the base current, always in the same direction, ie by a variable but not alternating current.

 All the superconducting devices are obviously kept in cryogenic chambers at an adequate temperature specific to the materials used and maintained by the energy produced by the system.

 The cooling of the ultrasonic elements is ensured by circulation of the insulating fluid, so as to maintain a constant temperature. The cavitation phenomenon can be limited by the existence of a pressurization.

 The various devices described above can be started or stopped from a conventional battery (12), through a heterodyne system (13) or any other means delivering an alternating voltage necessary for the system to ramp up only, which is very brief.

Claims (11)

 1) Device characterized in that it constitutes an electric, static, alternating generator, independent of any other external source of energy.  2) Device according to claim 1 characterized in that it uses to produce electrical energy, the force of ultrasound (22) whose power is amplified by interaction and mutual reinforcement in resonant cavities formed by the intervals of the plates (1) (2).  3) Device according to claims 1 and 2 characterized in that the excitation elements (1) and resonators (2) are calculated and arranged so as to vibrate together in synchronization on their own resonant frequency.  4) Device according to claims 1, 2 -and 3, characterized in that the materials used are suitable for producing an alternating polarization under the effect of a pressure force or an electric voltage, or for spontaneously polarizing, such as piezoelectric, ferroelectric and other electrostrictive, magnetostrictive materials ...  5) Device according to any one of the preceding claims, characterized in that the vibrating elements consist of a stack of blades of these different materials and of collecting armatures, forming a battery of plates (1) and (2), constituting at resonance, generator-capacitors connected in parallel or in series-parallel, according to the desired voltage or load.  6) Device according to any one of the preceding claims, characterized in that the alternating current (8) necessary for the tension of the exciter plates (1), generating ultrasound (22), is produced by an oscillating circuit RLC (8) (9) (1), the capacitor of which is constituted by the excitation plates (1) and the inductor by the superconductive coil (9), and the frequency of oscillation of the current of which is in resonance with the inherent vibrations of the assembly plates.  7) Device according to any one of the preceding claims, characterized in that the energy dissipated in the oscillating circuit is compensated by electromagnetic coupling on the alternating current (3) produced by the resonator blades (2), using coils superconductive (10), which neither alter nor decrease the original current (3) due to the absence of impedance of the superconductive windings of these coils.  8) Device according to any one of the preceding claims, characterized in that the windings of the superconductive coupling coils (10) may, when the Meissner effect is incomplete, require the addition of a capacitor (15) in series, forming an RLC circuit, so as to induce, at resonance, no reactance, therefore no impedance.  9) Device according to any one of the preceding claims, characterized in that each superconductive coil can be, as a function of the frequency, dissociated into two coils, so that each is crossed, using filters, only by alternation, ie by a variable but not alternating current.  10) Device according to any one of the preceding claims, characterized in that the RLC oscillating circuit can independently constitute, by itself (FIG 3) (8) (9) (1), an entirely alternating static electric generator superconductor, the residual dissipation of the base current (8) of which is self-compensated by inductive superconducting drawdown (10), therefore without losses. The creation of current and voltage being done by inductive superconductive coupling (20) without energetic alteration of the basic current (8) using batteries of superconductive coils (20).  The secondary windings (11) and (21) are in principle non-superconductive.  11) Device according to any one of the preceding claims, characterized in that the superconductive elements are maintained at the appropriate temperature in cryogenic chambers by the effect of the system's own energy.