PL232496B1 - Method for generation of voltage to produce electrical energy and the device for generation of voltage to produce electrical energy - Google Patents

Abstract

The developed method of generating voltage to produce electricity will allow the molecular energy of the illuminated solid to be released under the influence of solar energy and, as a result, induce voltage in the piezocrystalline material. The device for generating voltage for generating electricity has at least - one made of a material with a Young's modulus of not less than 100 [kN/mm2] - active element (1), placed on a movable platform (3) inside the housing (6). It is exposed to electromagnetic radiation, preferably near infrared light in the housing window (6). After reaching the assumed length, the elongated active element (1) presses on the lever system (8) and, through this system, on the piezo crystals (9), preferably all piezo crystal stacks (10). By applying short-term but repeated pressure on each piezopile, a voltage of millions of volts [V] is generated each time in a small device. The developed method and device enable the production of electricity as a result of a safe and fully controlled process, the nature, scale and results of which can be compared to the effects of energy release achieved in environmentally hazardous nuclear reactors.

Description

Description of the invention

The subject of the invention is a method of generating voltage for generating electricity and a device for implementing the developed method of generating voltage for generating electricity, which can be properly implemented and used in any place that is within the range of sunlight even for part of a day, regardless of the intensity. and the length of time that the place is exposed to the sun.

From the US patent application US 4236377 (Publ. US19780893047 19780403) there is known a device "Heat expansion machine" which was designed to work with the use of solar energy, so as to move the rotating wheel with as little energy loss as possible. . It can also operate on electricity or nuclear energy. Described herein is a thermal expansion gravity motor consisting of a frame, a rotating shaft supported by the frame, and a drive gear coupled to said rotating wheel. Wherein the drive gear has a plurality of teeth around its outer circumference and a plurality of drive rods. The drive wheel also has drive rods at one end pivotally attached to the gear around the circumference of the drive wheel to allow the drive rods to rotate within a predetermined range limited by the two teeth of the gear. The other end of each of the drive rods extends radially outward therefrom. The gear wheel also has a plurality of volume changing elements on its circumference. The at least one volume changing member is suitably positioned between the drive rods to vary the distance between the drive rods, and when the one or more expansion members are currently continuously active on one side of the engine by heating or cooling the expanding members, the gravity motor, more precisely, its circle consequently becomes asymmetrical between the two sides, and as a result it moves continuously. The described gravity engine further preferably comprises means for focusing the sun's rays on each expansion element, each expansion element being heated by solar radiation.

Also known from the patent application US 20110108020 (publ. US20090616419 20091111) is the invention entitled A "Ballast member for reducing active volume of a vessel" that can be placed on board to reduce the active capacity of the vessel through which the working fluid can circulate. For example, the solar power supply system may include a solar receiver through which the working fluid may be circulated and at least one solar collector which is designed to direct solar energy towards a solar energy receiver for heating the working fluid. The tank is in fluid communication with the solar receivers so that the working fluid can circulate in the tank. The reservoir includes an inner chamber and at least one ballast element inside the inner chamber that reduces the active capacity of the inner chamber.

The aim of the present invention is to indicate a method and, accordingly, to construct a device that will allow the release of the molecular energy of the illuminated solid under the influence of solar energy, and as a result generating a voltage in the piezo-crystalline material.

The essence of the method of generating voltage for generating electricity consists in the fact that active elements made of a material with Young's modulus not lower than 100 [kN / mm ² ] are placed in the housing on a movable platform, each of them in turn positioned in the window. Then, electromagnetic radiation, preferably near-infrared light, is directed onto the active element. As a result of its elongation by the assumed increase in length Al, it presses the lever system and activates it and transmits the pressure of the active element to the piezocrystals, preferably to all piezocrystalline stacks, through the lever system, which causes a potential difference used to generate electricity. Next, another active element is introduced into the window, and the one whose longitudinal extension has already been used is removed from the exposure zone in the window and introduced into the cooling sphere.

Preferably, the generated electricity - possibly after its appropriate conversion - is stored, for example, in batteries, or transferred, for example by supplying it to the power grid, or it is also used to directly supply electricity consumers.

Preferably, at least one sensor monitors the moment the active element achieves the assumed increase in length Al and the time during which it is exposed to electromagnetic radiation.

Preferably, the platform, which is the movable platform, is subjected to rotation after the heated active element has reached a predetermined length, and thus the next active element is exposed.

The active element is displayed in the window, preferably using a set of sensors, including photosensitive sensors, among the elements arranged on the perimeter of the movable platform.

Preferably, the active element placed in the window between the focusing mirrors is illuminated by rays of light reflected by the focusing mirrors.

Preferably, the focusing mirror placed on the top of the housing, reflecting the sun's rays feeding the optical fibers, illuminates the shadow zone of the active element.

Preferably, the focusing mirror is tilted or raised so that its surface is at an angle as close as possible to 90 °, most preferably at right angles to the sun rays incident on its surface.

Preferably, the active element, the longitudinal extension of which has already been used and which is removed from the irradiation zone in the window and introduced into the cooling sphere - is used to crush the piezocrystalline stacks in the cooling zone, preferably by means of an analogous lever arrangement.

Preferably, the generated electric current is supplied to at least one device participating in the implementation of the described method, preferably a lever system, a movable platform or devices used for heating the active element.

Preferably, in a cooling zone which is connected to the heat pump system, solar energy is transferred from the cooled active elements to the heating system.

The essence of the device for generating voltage for generating electricity intended to implement the method defined above consists in the fact that it has at least one active element made of a material with Young's modulus not less than 100 [kN / mm ² ] placed on a movable platform inside the housing, which it is irradiated with electromagnetic radiation, preferably near infrared light in the housing window, pressing - once it has reached a predetermined length - on the lever system, and through it on the piezocrystals, most preferably all piezocrystalline stacks.

Preferably, the device has twelve active elements.

Preferably, the set of piezocrystalline stacks is composed of piezocrystalline disks, and that of piezocrystals whose total deformation required to obtain the piezo effect is equal to the pitch translated by the lever system caused by the expansion of the active element.

Preferably, the number of piezocrystalline disks is sufficient to achieve the piezo effect due to the force generated by the active element.

Preferably, the movable platform is a rotating or swinging platform.

Preferably, this device has a focusing mirror in the upper part of the housing with the optical fiber led out in the housing window facing the active element.

Preferably, the active element is a solid with a circular cross section, preferably a solid cylinder or a tube or a cylinder with longitudinal hollows.

Preferably, the active element is additionally equipped with heating elements disposed directly therein or near it.

Preferably, the surface of the active element is black or is covered with a substance that absorbs light and heat.

Preferably, focusing mirrors, preferably parabolic mirrors, are arranged in the window of the device.

Preferably, the focusing mirrors are movable.

Preferably, the focusing mirror has a length at least equal to the length of the active element, and the width or diameter is at least twice the width of the active element.

Preferably, the device has at least one focusing lens focused on the active element.

Preferably, the focusing mirror is directed toward the sun and includes a mechanism to orient it toward the sun.

Preferably, a cooling sphere is separated outside the window, preferably with a system of levers transmitting the pressure of the contracting active element to piezocrystalline stacks.

Preferably, the cooling zone is connected to the heat pump brine system, in which the solar energy is transferred to the heating system.

Preferably, the device for generating a voltage for generating electricity is connected to the converter or the battery.

PL 232 496 Β1

The correct course of the developed method and the effective operation of the developed device are possible regardless of whether the sun's rays fall on the active element directly or through a layer of clouds, and also regardless of the time in which the device is exposed to the sun's rays.

By applying a short-term but repeated pressure to each piezostos, a voltage of millions of volts [V] is generated.

Due to the fact that the elongation of a solid depends only on its initial length, the coefficient of linear expansion and temperature change, but it does not depend on the initial temperature T - therefore the device implementing the developed method can work in all temperature conditions, in any climate, after the previous its adaptation to changes that will be subject to active elements in a specific environment.

The developed device will not require any special supervision or activity, or even the presence of a human being. Therefore, it will be able to work in hard-to-reach conditions, for example, it will be able to be used to illuminate islands, the shoreline, or important objects in places where it is difficult or even impossible to provide a traditional power supply.

Additionally, the possibility of using the heat received from the cooled active elements in the cooling zone and introducing this heat to the lower source of the heat pump - enables the use of this part of solar energy, leading to an increase in the heat pump operating parameters.

By implementing the described method, a voltage of millions of volts [V] is generated in a device of small dimensions. The developed method and device make it possible to generate electricity as a result of a safe and fully controlled process, the nature, scale and results of which can be compared with the effects of energy release, which are achieved in environmentally dangerous nuclear reactors.

The device constituting the subject of the invention has been presented in the embodiment in the drawings, in which Fig. 1 - shows a side view of the developed device with a mirror focusing the light visible in its upper part, concentrating and amplifying the flow of light fluxes in the optical fibers led from this place, Fig. 2 - shows a cross-section of the device housing with a movable platform of active elements and with visible - placed between the focusing mirrors - an activated active element that absorbs solar radiation, and fig. 3 - shows a longitudinal section of the housing with one, just activated active element shown here, illustrating the principle of the lever operation exerting pressure on the piezo, which pressure is exerted by the expanding active element, here in the form of a cylinder.

It is known that a change in temperature changes the dimensions of an object. This relationship, which was used in the developed invention, is described in the example in which a bar of length /, with a temperature T, was heated by / 17, which caused its elongation by Al. The end length of the bar at T + AT is / + Al. Studies for construction materials have shown that the dependence of the length change on the temperature change is linear, which can be written as follows:

l + ΔΙ - i + Ια _ο ΔΤ where: / - is the initial length of the bar, Al - elongation, and ₀ - linear expansion coefficient, and / 17- temperature change.

Therefore, by selecting the appropriate material from which the active element 1 will be made in the method and device constituting the subject of the invention, it can be predicted what change in its length will occur after exposure to light or directly after heating it. Indication of the material with optimal properties, or composition of the alloy with appropriate properties, must take place during the implementation stage of the present invention and requires the conduct of the research.

On the other hand, another dependence, the existence of which was used in the developed invention, results from the law of mechanics, describing the dependence of strain on stress. It is described by Hooke's law and the related principle of uttensio sic vis (what elongation is such a force). Initially, the deformation of the body under the influence of the force acting on it is proportional to this force.

Taking into account the above dependencies, it can be assumed that in a cylinder with an initial height not exceeding 1 meter [m] and similarly not exceeding a diameter of 0.5 meter [m], which is exposed to sunlight, internal stresses will be generated, as a result of which the cylinder it will lengthen, while its elongation by even a small amount of A / will release the pressure force sufficient for its lower and upper posture to exert pressure with a force reaching even 27 tons [t].

PL 232 496 B1

The developed method for generating electricity consists in that an active element 1, preferably one of twelve active elements 1, is selected and arranged substantially vertically - electromagnetic radiation, preferably light, is directed. In an embodiment, a process is described in which light is used, i.e. the visible part of electromagnetic radiation, otherwise known as visible radiation, which is received by the retina of the human eye, in the electromagnetic wavelength range depending on the individual eye sensitivity of a given person, usually 380-780 nanometers [nm]. Nevertheless, the process will be similar also in the case of using direct thermal radiation (called thermal radiation, or temperature radiation) to obtain the elongation of the active element 1, i.e. electromagnetic radiation emitted by electrically charged particles as a result of their thermal movement in matter. Atoms and molecules with a temperature above absolute zero have kinetic energy, the use of which can lead to unexpected results, the scale of which is surprisingly large. This energy is changed as a result of the interaction of atoms and molecules, which changes in energy result from acceleration or dipole oscillation of charges, leading to the production of electromagnetic radiation.

The expanding active element 1 is preferably made of steel, possibly copper [Cu] or alloys of selected metals, or of another material with a high Young's modulus [E] of at least 100 [kN / mm ² ] - modulus of linear deformation also known as the modulus (coefficient) of longitudinal elasticity. The active element 1 can be any solid, for example circular in cross-section, preferably a solid cylinder or a tube, or a cylinder with longitudinal hollows that will minimize lateral deformations of the active element 1. The active element 1 can be additionally equipped with heating elements located directly in it or in its vicinity. The surface of the active element 1 is black or covered with a light and heat absorbing substance, the presence of which enhances the longitudinal stretching effect of the active element 1.

Uniform heating of the entire surface of the active element 1, also in the rear, shaded part of the exposed space, is ensured by mounting the ends of the optical fiber 2 here.

Active elements 1 - which are preferably twelve, and can be any number depending on how much energy we want to obtain and what will be the heating and cooling time to obtain a full return cycle - are placed on a movable platform 3, which, when the heated active element reaches 1 of a predetermined length is rotated, and thus the next active element 1 is exposed to the radiation.

The selected active element 1 is influenced for as long as it is necessary to obtain its elongation by the assumed increase in length Al, which is laoAT and is the product of the initial length I, the linear expansion coefficient a o of the material from which the active element 1 was made and the temperature increase by which it must be heated AT.

The time necessary to obtain the assumed temperature increase AT, and as a result of this increase in the length of Al, of course also depends on other factors, including the intensity of radiation (e.g. solar), the intensity of which is directly reflected in the course of the process. And yes, this time can be determined by several methods. Preferably, sensors are used to monitor the moment when the active element 1 obtains the expected dimensions. In principle, however, it is assumed that the active element 1 will lose its equilibrium after achieving its enlarged dimensions and due to the action of the ratchet mechanism and gravity forces it will slide out of the window 4 in which it was activated, and on its place automatically - with the use of a ramp - another active element will slide in 1.

The light to which a given active element 1 is exposed - is directed directly and / or optical fibers 2 onto this one of several or a dozen or so active elements 1 within an organized group of analogous active elements 1 positioned on a rotating - preferably inclined - platform 3 which it projects periodically to the action of the light in the window 4, and which is inserted and placed between the focusing mirrors 5, preferably sliding apart and opening and then closing the sides of the focusing mirror 5.

The focusing mirror 5 preferably has the length of the active element 1 and its width or diameter is at least twice as large as it, and is preferably a parabolic mirror. Its task is to focus the sun's rays into one point, a task that can also be accomplished by a lens or converging lenses.

A feature of the conducted process is repeatability in cycles closed by the so-called repeat point. Another one, waiting among the peripherally arranged, preferably rotatable, mobile platform 3

PL 232 496 Β1 active element 1 is displayed in the window 4 by any known mechanism, for example by the movement of the moving platform 3, controlled by a set of sensors, including photosensitive sensors. As explained above, the active element 1 is activated substantially throughout its entire mass, because it is subjected to the direct light directed at it, additionally concentrated by the focusing mirrors 5 in the window 4, and additionally due to the fact that in the shadow zone it is exposed to light provided here by optical fibers 2 powered by a focusing mirror 7.

The rotating, mobile platform 3 with active elements 1 placed thereon is placed in an insulating casing 6, at the top of which a focusing mirror 7 is placed, which concentrates the sun's rays supplying optical fibers 2, which are then output in the shadow zone of the active element 1.

Thanks to the operation of known control sensors, or, for example, gas actuators, the focusing mirror 7 follows the sun in the sense that it automatically goes towards the sun, and the focusing mirror 7 itself tilts or raises so that its surface is optimally aligned, most preferably at right angles to the sun rays incident on its surface, such that it always draws the maximum dose of radiation.

In this way, the active element 1 is heated and brought to its predetermined length, and as a result of its elongation, a system of levers 8 is activated to transfer the pressure of the active element 1 to all piezocrystals 9, and more preferably to all essentially consisting of ten piezocrystals 9 each piezocrystalline stacks 10 and possibly additionally multiplying this effect.

The lever 8 system also uses the principle that the arms of the two-armed (two-arm) lever are also arms of appropriate forces (they are perpendicular to them) from which the formula for the so-called lever gear:

Ρί ₌ £ and Pl T ~ 2, and the force applied to the lever is inversely proportional to the length of its arm. Hence, by setting the gear of the lever 8, i.e. the ratio of the lengths of the arms of the lever 8, it is selected what force gain, i.e. how many times greater force resulting from the expansion of the active element 1, we want to achieve in order to influence the piezocrystalline stacks 10.

Thus, the longitudinal expansion of the active element 1 is translated, via a system of levers 8, into piezocrystals 9, preferably stacked 10, in which a potential difference between the opposite walls of the crystal is caused by mechanical stress. By the same pressing on the piezocrystalline stacks 10, a short-term potential difference is induced and the generated voltage can be transformed into electrical energy.

As it was established, pressing with a force of 2 kilonewtons [kN] on a quartz cube with sides of 0.01 meter [m] causes a voltage of 12 500 volts [V] on its opposite sides,

A set of piezocrystalline stacks 10 (piezocrystalline stacks) is constructed of piezocrystalline disks selected so that the summative deformation required to obtain the piezo effect, expressing the component of the necessary deformations of individual piezocrystals 9 and piezocrystalline stacks 10, corresponds to the correspondingly translated and adapted pitch of the lever system 8 caused by the expansion of the active element 1. The number of disks is adjusted to the force generated by the active elements 1 and the sum compression they will undergo.

The activated active element 1, the longitudinal expansion of which has already been used, after its removal from the irradiation zone in window 4, is introduced into the cooling sphere 11 where it is cooled down to the initial temperature. The following shrinkage of the active element 1, which is used - similarly with an analogous arrangement of the levers 8 - to crush successive piezo-crystalline stacks 10. Thus, both the expansion energy and the contraction energy of the individual active elements 1 are used.

The cooling zone 11 is connected to the heat pump's ground source system, in which solar energy is transferred to the heating system, increasing the operating parameters of the heat pump.

Each time pressing on each disk and piezocrystalline stack 10 is produced a voltage of millions of volts [V],

PL 232 496 B1

The high voltage electricity generated - possibly after appropriate conversion - is stored, for example in batteries. Or it is forwarded, for example supplied to the power grid, or it is used to directly supply electricity consumers, for example the devices described above: the lever system 8 or the mobile platform 3, if their operation requires power. Easily accumulated electric energy, which is obtained as a result of the implementation of the developed method - is then used in its small part to heat the active element 1 in shaded places or in a non-sunny period, for example at night, when it is not exposed to light .

This possibility arises because of the large difference between the amount of energy needed to heat the active element 1 and the amount of energy obtained by insolation and elongation of the active element 1.

P r z y k ł a d r e a l i z a c j i I:

Ten active elements 1 made of steel, 0.5 meters [m] high and 0.1 meters [m] in diameter 0, are placed on the rotating, mobile platform 3. Initially, active elements 1 have an ambient temperature of 20 ° C.

By spreading the sides of the focusing mirror 5, a selected one of the active elements 1 is introduced into the window 4 and activated here by exposing it to sunlight. In addition, focusing mirrors 5 are focused on it, and in the shaded zone it is illuminated with optical fibers 2 powered by the focusing mirror 7 embedded in the upper part of the housing 6, heating the active element 1 in its entire mass. This process is carried out until the temperature of the active element 1 rises by one degree Celsius [° C]. The time necessary for the expected heating of the active element 1 depends individually on the changing environmental conditions (including the degree of insolation) and the characteristics of the active element 1 (in this case the linear expansion coefficient of steel a0). Obtaining the elongation of the active element 1 with the expected increase in length Λί amounting to 0.001 meters [m] is recorded with a sensor supervising the course of the process.

Internal stresses are induced in the activated, heated and expanding cylinder of the active element 1, as a result of which its lower and upper positions exert a force of about 20 tons [t]. In this way, pressure is exerted on the arrangement of the levers 8, which transfer the pressure in a ratio of 44: 1 to the piezocrystals 9 stacked in the stacks 10.

The sets of piezocrystalline stacks 10 (piezostos) are previously assembled from piezocrystalline disks so selected that their summation deformation corresponds to the movement of the levers activated by the active element 1.

On the other hand, the piezocrystals 9 used in this case, in order to induce the piezoelectric effect in them, consisting in the appearance of electric charges on their surface under the influence of mechanical stress, require compression so that their surface temporarily deforms by a few microns.

Thereby, pressing on the piezocrystalline stacks 10 produces a short-term potential difference, sufficient to generate electricity, since the mechanical stress induces a potential difference between the opposing walls of the piezocrystals 9. At the critical moment, when the electrical polarization is at its greatest under stress, the electric charge at the edges of the crystal is discharged. With the described, single, short-term operation of the lever system 8, a voltage of about 2 million volts [V] is generated in the described system.

The activated active element 1 - the longitudinal extension of which has already been used - after its removal from the irradiation zone in window 4, is introduced into the cooling sphere 11, where it is cooled down to the initial temperature.

Another active element 1, waiting among the perimeter rotating, movable platform 3, is displayed in the window 4 using the ramp mechanism and using the movement of the rotating, movable platform 3 controlled by a set of sensors, including photosensitive sensors.

On the other hand, the generated high-voltage electricity is stored in batteries, from where it is sent to the power grid.

P r z y k ł a d r e a l i z a c j i II:

Twelve active elements 1 made of tungsten 1, 0.3 meters [m] high and 0.1 meters [m] in diameter 0 are placed on the rotating, mobile platform 3. Initially, active elements 1 have an ambient temperature of 15 ° C.

PL 232 496 B1

By spreading the sides of the focusing mirror 5, a selected one of the active elements 1 is introduced into the window 4 and it is activated. Here, the active element 1 is exposed to sunlight and the lenses and focusing mirrors 5 are focused on it, and additionally, in the shaded zone, it is illuminated by optical fibers 2 powered by the focusing mirror 7 embedded in the upper part of the housing 6, heating the active element 1 in its entire mass after some time by 5 degrees Celsius [° C]. The time required for the expected heating of the active element 1 depends on the changing environmental conditions (including the degree of insolation) as well as the characteristics of the active element 1 (including the linear expansion coefficient of steel aj). Obtaining the expected extension of the active element 1 by an increase in length Al of 0.004 meters [m] causes the active element 1 to automatically slide out of the irradiation zone because when enlarged, losing its balance, it slides out of the place where it was enlarged, and the next one automatically slides in its place. .

In the activated, heated active element 1, internal stresses are created, as a result of which it elongates, and its lower and upper positions exert a pressure of about 15 tons [t] on the system of levers 8, which transfer this pressure in a ratio of 20: 1 to piezocrystals 9 arranged in piles 10, in which, under the influence of mechanical stress, the formation of a potential difference between the opposite walls of the crystal is caused.

The sets of piezocrystalline stacks 10 (piezostos) are made of piezocrystalline disks selected in such a way that their total deformation necessary to achieve the piezo effect is adjusted to the necessary pressure, calculated earlier and shifted by the arrangement of the levers 8 caused by the expansion of the active element 1, which is 0.004 meters [m].

Thereby, pressing on the piezocrystalline stacks 10 induces a short-term potential difference sufficient to generate electricity.

By actuating the lever system 8 briefly as described above, a voltage of approximately 3 million volts [V] is generated.

The activated active element 1 - the longitudinal expansion of which has already been used - after its removal from the irradiation zone in window 4, is introduced into the cooling sphere 11 where it is cooled down to the initial temperature. On the other hand, the following shrinkage of the active element 1 is used - similarly by means of a gear and an analogous arrangement of the levers 8 - to crush successive piezo-crystalline stacks 10. Thus, both the expansion energy and the contraction energy of the individual active elements 1 are used.

The cooling zone 11 is connected to the heat pump's ground source system, in which solar energy is transferred to the heating system, increasing the operating parameters of the heat pump.

Another active element 1, waiting among the peripherally arranged rotatable mobile platform 3, is displayed in the window 4 using any known mechanism and using the movement of the rotating mobile platform 3 controlled by a set of sensors, including photosensitive sensors.

On the other hand, the generated high-voltage electricity - after its appropriate processing - is stored in batteries, from where it is partly used to directly supply electric energy receivers: the lever system 8 and the mobile platform 3, and partly it is sent to the power grid.

Claims (27)

Patent claims 1. A method of generating voltage for generating electricity, where electromagnetic radiation, preferably light in the near infrared range, is directed to the active elements, as a result of which the active element is elongated by an assumed increase in the length of Al, thus the active element presses on the piezocrystals, preferably all piezocrystalline stacks and the active element, the longitudinal extension of which has already been used, is removed from the irradiation zone in the window and introduced into the cooling sphere, characterized in that the active elements (1) made of a material with Young's modulus not lower than 100 [kN / mm ² ] is placed in the housing (6) on the mobile platform, each of them in turn is positioned in the window (4) and then the active element (1), after its extension by the assumed length increase Al, presses the lever system (8), then introduces another active element (1) appears in the window (4). PL 232 496 B1 2. A method of generating a voltage for generating electricity according to claim 1. A method as claimed in claim 1, characterized in that the generated electricity - possibly after appropriate conversion - is stored, for example, in batteries, or is transferred, for example, by supplying it to a power grid, or is used to directly supply electricity consumers. 3. A method of generating a voltage for generating electricity according to claim 1. The method according to claim 1 or 2, characterized in that at least one sensor monitors the moment of obtaining the assumed increase in length Al by the active element (1) and the time during which it is subjected to electro-magnetic radiation. 4. A method of generating a voltage for generating electricity according to claim 1; A method according to claim 1, 2 or 3, characterized in that the platform, which is a mobile platform (3), is rotated after the heated active element (1) has reached a predetermined length, and thus the next active element (1) is exposed to radiation and another, among the peripherally arranged movable platform (3), the active element (1) is exposed in the window (4), preferably using a set of sensors, including photosensitive sensors. 5. A method for generating a voltage for generating electricity according to one of the claims 1 to 5. A method as claimed in 1 to 4, characterized in that the active element (1) placed in the window (4) between the focusing mirrors (5) is illuminated by rays of light reflected by the focusing mirrors (5). A method for generating a voltage for generating electricity according to one of the claims from 1 to 5, characterized in that the focusing mirror (7) placed on the top of the housing (6) reflecting the sun rays feeding the optical fibers (2) illuminates the shadow zone of the active element (1). A method of generating a voltage for generating electricity according to one of the claims A method according to any of the claims 1 to 6, characterized in that the focusing mirror (7) tilts or raises its surface so that its surface is at an angle as close as possible to 90 °, most preferably at right angles to the sun rays incident on its surface. A method for generating a voltage for generating electricity according to one of the claims from 1 to 7, characterized in that the active element (1), the longitudinal expansion of which has already been used and which is removed from the irradiation zone in the window (4) and introduced into the cooling sphere (11) - is used to crush piezocrystalline stacks ( 10) located in the cooling zone (11), preferably by means of an analogous arrangement of the lever (8). A method for generating a voltage for generating electricity according to one of the claims 1 to 9. A method according to any of the claims 1 to 8, characterized in that the generated electric current is supplied to at least one device involved in the implementation of the described method, preferably a lever system (8), a movable platform (3) or devices used to heat the active element (1). A method for generating a voltage for generating electricity according to one of the claims 1 to 10. A method according to any of the claims 1 to 9, characterized in that in a cooling zone (11) that is connected to the heat pump system, solar energy is transmitted from the cooled active elements (1) to the heating system. Device for generating a voltage for generating electricity for carrying out the method as defined in one of the claims from 1 to 10, characterized in that it has at least one active element (1) made of a material with Young's modulus not lower than 100 [kN / mm ² ] placed on the mobile platform (3) inside the housing (6), which is subjected to irradiation with electromagnetic radiation, preferably with light in the near infrared range, in the window (4) of the housing (6), pressing - after it reaches the assumed length - on the lever system (8), and through this system on the piezocrystals (9), preferably all piezocrystalline stacks (10). 12. A voltage generator for generating electricity as claimed in claim 1. 11. The device of claim 11, characterized in that it has twelve active elements (1). 13. Device for generating a voltage for generating electricity as in claim 1. The method according to claim 11 or 12, characterized in that the set of piezocrystalline stacks (10) consists of dys10 This is the piezocrystalline one from the piezocrystals (9), the total deformation of which required to obtain the piezo effect is equal to the pitch translated by the lever system (8) caused by the expansion of the active element (1). 14. Device for generating a voltage for generating electricity as in claim 1, The method according to claim 11, 12 or 13, characterized in that the number of piezocrystalline disks (10) is sufficient to obtain the piezo effect as a result of the force generated by the active element (1). 15. Device for generating a voltage for generating electricity according to one of the claims 1 to 5. 11 to 14, characterized in that the movable platform (3) is a rotating or a swinging platform. A device for generating a voltage for generating electricity according to one of the claims 1 to 16. A focusing mirror (7) with an optical fiber led out in the window (4) of the housing (6) directed towards the active element (1), is arranged in the upper part of the housing (6). 17. Device for generating a voltage for generating electricity according to one of the claims 1 to 6. according to 11 to 16, characterized in that the active element (1) is a solid with a circular cross-section, preferably a solid cylinder or a tube, or a cylinder with longitudinal cavities. The device for generating a voltage for generating electricity according to one of the claims 11 to 17, characterized in that the active element (1) is additionally equipped with heating elements arranged directly therein or near it. 19. Device for generating a voltage for generating electricity according to one of the claims according to 11 to 18, characterized in that the surface of the active element (1) is black or is covered with a substance that absorbs light and heat. 20. Device for generating a voltage for generating electricity according to one of the claims 1 to 20. 11 to 19, characterized in that converging mirrors (5), preferably parabolic, are arranged in the window (4). 21. Device for generating a voltage for generating electricity according to one of the claims 1 to 2. 11 to 20, characterized in that its focusing mirrors (5) are movable. 22. Device for generating a voltage for generating electricity according to one of the claims 1 to 22. 11 to 21, characterized in that its focusing mirror (5) has a length at least equal to the length of the active element (1), and its width or diameter is at least twice the width of the active element (1). 23. Device for generating a voltage for generating electricity according to one of the claims 1 to 23. A device according to 11 to 22, characterized in that it has at least one focusing lens focused on the active element (1). 24. Device for generating a voltage for generating electricity according to one of the claims 1 to 24. 11 to 23, characterized in that the focusing mirror (7) is directed towards the sun and contains a mechanism for directing it towards the sun. 25. Device for generating a voltage for generating electricity according to one of the claims 1 to 5. 11 to 24, characterized in that a cooling sphere (11) is separated in the housing (6) apart from the window (4), preferably with a lever arrangement (8) that transfers the pressure of the contracting active element (1) to the piezocrystalline stacks (10). A device for generating a voltage for generating electricity according to one of the claims 1 to 26. from 11 to 25, characterized in that the cooling zone (11) is connected to the heat pump heat source system, in which solar energy is transferred to the heating system. 27. Device for generating a voltage for generating electricity according to one of the claims 1 to 27. from 11 to 26, characterized in that it is connected to a converter or a battery.