IT202100025268A1 - ELECTRODYNAMIC INERTIAL ELECTRIC ENERGY ACCUMULATOR - Google Patents

Description

ELECTRODYNAMIC INERTIAL ELECTRIC ENERGY ACCUMULATOR

DESCRIPTION

The present invention refers to an electrodynamic and mechanical energy accumulator, also called electrodynamic accumulator.

The energy? necessary to carry out any transformation and for life itself. Are there more energy sources? different types and are applicable in most? different ways. Our body itself draws chemical energy from food and, normally to a lesser extent, from drinks and transforms it into thermal energy and mechanical energy.

In industrial practice, energy is There? which allows all processes and is supplied to the plants in different ways (electricity, steam, fuel and the like).

The greatest form of energy? valuable? the electric one, which has the highest yields? high and does not produce direct harmful emissions. However, although? production can be planned to a large extent, but such planning is rarely possible? perfect and alternating periods in which production is insufficient for periods in which production is much more? high in consumption. This fact would lead, in itself? to a waste of electricity which always entails rather heavy economic damage and, sometimes, even ecological damage, given that fossil or electrochemical sources are often used for the production of electricity.

To try to avoid, or at least reduce, this waste, accumulators have been created. These are electrochemical reactors, in which chemical substances are transformed into electrical energy or electrical energy into chemical substances, normally in an almost reversible manner. Yes ? called ?almost reversible? because, in reality, accumulators lose their capacity over time? to transform chemical energy into electrical energy and vice versa, with the result that, at a certain point, said accumulators are no longer? capable of producing or storing electricity and must be eliminated and replaced.

The disposal of accumulators presents non-trivial aspects. Normally, accumulators include a casing, usually made of a plastic material, which must be disposed of as such. Inside the container there are electrolyte solutions, often including ions of heavy metals or mineral acids, which cannot be released painlessly directly into the environment. Finally, there are the electrodes, also normally made of heavy metal or metal oxide or graphite. For this reason, normal electrochemical accumulators, while allowing energy to be conserved for subsequent use, are nevertheless non-negligible sources of pollution and must be managed correctly. which involves non-negligible additional costs, what's more? often not exactly transparent.

WO2007/116 040, by the same inventor as the present invention, describes a power plant that exploits gravitational masses in the management of a dynamo or an alternator.

Batteries are also widely used in the case of electricity produced from renewable sources. Many of the production techniques have trends that are in no way programmable: time of day dependent on the season for the production of energy from the sun, unpredictable wind regime for the production of wind energy, and so on. Street.

This trend in renewable sources has led to the study of new solutions for accumulating the energy produced that cannot be used immediately, alongside the use of normal electrochemical accumulators.

One of the best ways? promising? was to use the excess electricity produced to carry out the electrolysis of water. In this way we obtain hydrogen, which can? be accumulated and stored. When will we need more again? energy, part of the hydrogen obtained is burned, using the energy produced. In this way, hydrogen becomes an important energy vehicle, without the need? of wasting all the electrical energy necessary for the electrolysis of water, given that it would be energy that would be wasted anyway.

Use hydrogen as an energy accumulator and so? to manage the excess energy produced? an advantageous technique. However, hydrogen still has some drawbacks. It is a highly flammable and sometimes even explosive substance, so its storage and preservation are not exactly simple. Furthermore, the electrolysis of water involves -how ? known and widely documented - very high overvoltages, so ? a process that is inadvisable in the presence of non-renewable energy sources.

It is, therefore, desirable to find a way to accumulate energy, which does not involve the emission of harmful or polluting substances, and which cannot give rise to risks of fire or other unfavorable events and which does not require the disposal of materials or environmental restoration. In particular, ? Is it advantageous to exploit gravitational and electromechanical energy to amplify a quantity? of input energy.

Problem underlying the invention? to propose an energy multiplier and accumulator that overcomes the aforementioned drawbacks and that allows incoming electrical energy to be managed without introducing polluting substances into the environment and regardless of the use of materials that are difficult to dispose of. This purpose is achieved through an energy accumulator, in which energy is stored in the form of mechanical energy, comprising a stator (2) and a rotor (1), characterized by what? that a second stator (3) ? integrated with the first and has the rotor of the reversible electrodynamic system in common with the first stator, the two stators (2; 3) being arranged concentrically, one outside and one inside the rotor (1). The subordinate claims describe characteristics preferences of the invention.

Further characteristics and advantages of the energy accumulator according to the present invention will however be better evident from the following detailed description of a complete operating cycle based on a preferred embodiment thereof, provided by way of example and not by way of limitation and illustrated in the drawings attachments, in which: fig.1 ? a simplified front view of the inertial system of the energy accumulator according to the present invention; And

fig.2 ? a schematic side view of the inertial system of the energy accumulator according to the present invention.

Fig. 1 ? a simplified plan view of the mechanical energy accumulator - which can? also be defined as electrodynamic - according to the present invention. The mechanical energy accumulator first of all includes an electrodynamic system, consisting of a rotor 1, enclosed between an internal stator 2 and an external stator 3, concentric. Each of the two stators 2; 3 can? work independently of each other 3; 2 or in programmed synergy; how already? said, it is always a reversible electric machine, therefore the rotor-stator system can? engage electrical power to generate mechanical torque, or can? generate electrical power using mechanical energy. For clarity, rotor 1 preferably has inductive windings both internally (facing the internal stator) and externally (facing the external stator). Rotor 1 rotates around a rotation axis 4. Furthermore, how can this be done? see in fig. 2, the rotor 1 includes a further mass 5, integral with it, which determines the necessary inertia. Mass 5? coupled to rotor 1 on one of the two base surfaces of the latter, that is? on one of the two surfaces which has the normal parallel to the longitudinal axis of rotor 1, so that the mass 5 protrudes from the assembly of rotor 1, internal stator 2 and external stator 3 in the direction of the rotation axis 4. Mass 5 has a central axis of symmetry, which coincides with the rotation axis 4 of the inertial electrodynamic system.

Referring again to fig. 2, the inertial electrodynamic system? advantageously integrated by masses constrained to move along radial axes with respect to the circumference of the circular mass integral with the rotor; these masses, being able to flow radially in two directions (towards the center or towards the outside), will amplify or attenuate the effect of the gravitational field, functionally to the position of the oscillation axis with respect to the action of the field itself (axis outgoing radial pointing downwards or pointing upwards). In this way an increase in efficiency is obtained, both in terms of inertia referred to the circular mass integral with the rotor, and in terms of contribution of the gravitational field thanks to the masses oscillating radially to the rotor, of the accumulator according to the present invention. The radially oscillating masses 6 are made up of a housing 7, a spring 8, the oscillating mass itself 9, and a system capable of locking or unlocking the position of the mass at precise distances from the center of rotation, and functionally of the speed ? of rotation of the rotor. The oscillating mechanisms 6 are coupled to the mass 5, so that each compression axis of each spring 8 has a radial direction with respect to the rotor 1. The combination of rotating masses and radially oscillating masses allows the gravitational action to be fully exploited . A further advantage occurs in the presence of synchronization systems (of a known type), which can be mechanical, electronic or electromechanical.

In a preferred embodiment, the system is operated in an optionally vertical plane of rotation, so that the oscillating mechanisms 6 (mass and related constraints) have a dual function, the first as axial dynamic inertial devices for energy storage, while the second function ? that of making the system put into rotation - the rotor 1, the mass 5 and the oscillating mechanisms 6 themselves - more invariant with respect to the slowing down of the rotation under the braking effect of the opposing resisting couple of the electrodynamic system (stators-rotor).

Firstly, inertia increases due to the increase in weight that these oscillating mechanisms 6 entail, why? how much more? great ? the rotating mass, more? will it be difficult? then stop it and, in this case, once rotor 1 has been started and brought up to speed, there will be a greater quantity? of kinetic energy to be recovered in the form of electrical energy and the action of producing electrical energy will last? more? in time. Furthermore, centrifugal force moves these masses away from the center of rotation, which also leads to an increase in capacity. of accumulation.

On the other hand, the system self-regulates in speed, thanks to the blocks and constraints present on the masses which do not allow their free movement and make them arrange themselves in housing 7 according to the interactions of the forces of these constraints and of the rotation, the all based on the best amplification of the inertia during the release phase (from mechanical to electrical) and the acceleration of the system during the charging phase (from electrical to mechanical). That is, for greater clarity, on the mass 5 integral with rotor 1 and/or on the oscillating mass 9 there are blocks and constraints to obtain the best performance, depending on the amplification between input energy and output energy, of rotor 1.

The oscillating mechanisms 6 exploit the gravitational field to facilitate the rotation of the rotor 1, determining an elongation of the oscillating masses 9 in the phase of concordance with the centrifugal force (travel towards the bottom dead center), and a recall of the same in the phase of discordance with the centrifugal force (travel towards the top dead center), as a function of the elastic constraints (compressed/loaded by the gravitational force and extended/unloaded by the gravitational force and the centrifugal force, with automatic mechanical block as a function of regulating the oscillations of the masses).

The use of the energy accumulator occurs in two main phases, one in which it is used as a user of the electricity grid, to accumulate energy and the other, in which it is used as a generator in order to supply electricity.

Before starting, the mass 5 ? stops, the mass 9 ? stops in the lowest position? low, the spring 8 ? discharged, rotor 1 and stators 2, 3 are de-powered and stopped.

In the first phase, also called the charging or energy accumulation phase, the internal stator 2, the external stator 3 and the rotor 1 are powered, so that the rotor 1 is set to rotate, then, once the speed has been reached? rotation speed, all electrical components are de-energized. The mass 9 is raised to the maximum height by a special motor, not shown in the figures. In inertial rotation the system possesses the energy of the mass 5 integral with the rotor 1 and the energy of the oscillating mechanisms 6. As described above, the gravitational field combined with the weight of the oscillating mass 9 produces a force which, depending on the rotation position of the oscillating mechanism 6, concorder? with the gravitational force, therefore moving the oscillating mass 8 away from the rotation axis 1 or it will not agree? with the gravitational force, therefore bringing the oscillating mass 9 closer to the rotation axis. This interaction between the two forces d? gives rise to an action of amplification of the tendency for rotor 1 to remain in rotation.

In a second phase, also called the discharge or transfer of electrical energy phase, the energy amplifier is connected to the electrical network as a generator, in such a way that the rotor, dragged by the mass attached to it, becomes an electrical energy generator , transforming into electricity? the mechanical torque of the inertial masses, so as to release electrical energy from the mechanical energy possessed by rotor 1. In this phase, the electrical energy, introduced by the electrical load, is partially compensated by the differential between the masses of the system ? mass 5 integral with the rotor 1 and oscillating mass 9 of the oscillating mechanism 6- and the resisting torque itself, due to the rotor which must produce electrical energy through the electrodynamic interaction with the stators. Furthermore, the presence of the two stators? internal stator 2 and external stator 3 - and the relative concentric arrangement allow the electrodynamic system (precisely rotor-stators) to have a multiplicity? polarity between the inductive windings of the internal stator 2 and those present in the internal part of the rotor 1 (first electrodynamic interaction) and a second multiplicity? polar between the inductive windings located on the external part of the rotor 1 and those present on the external stator 3 (second electrodynamic interaction); the interactions can occur by determining different electrical combinations between them. Precisely, the internal inductances of the rotor ? are located in the hollow area with a radius smaller than R1 - do they link the field flux with the inductances of the internal stator 2? are located in the outer surface of the inner stator-; the external inductances of the rotor? are located on the external surface with a radius greater than R2 - do they link the field flux with the inductances of the external stator 3? they are located in the hollow surface with a radius smaller than R3-, therefore the stators will be able to work independently or synergistically with each other.

The fact that the stators can work independently allows various combinations, including, for example, one of the two to produce a contribution to the rotation of the rotor even in the energy discharge phase, using part of the energy to keep the rotor rotating 1 during the discharge phase, prolonging this phase, possibly thus giving periodic impulses, so? to prolong the rotation of rotor 1 even during the discharge/transfer of electrical energy.

The present invention allows you to exploit gravitational and electromagnetic energy to amplify a quantity? of incoming energy, obtaining benefits, even if for a limited period of time. That is, it allows you to keep a certain quantity stored. initial energy supply, limiting losses and avoiding the use of electrochemical systems, which are often polluting.

It is understood, however, that the invention must not be considered limited to the particular arrangement illustrated above, which constitutes only an exemplary form of execution thereof, but that various variations are possible, all within the reach of a technician in the art, without thereby departing from the The scope of protection of the invention itself, as defined by the following claims.

LIST OF REFERENCE CHARACTERS

1 Rotor

2 stator

3 stator

4 spindle (of 1)

5 mass

6 oscillating mechanisms

7 accommodation

8 spring

9 oscillating mass

R1 radius

R2 radius

R3 radius

Claims (10)

1) Energy accumulator, in which energy is stored in the form of mechanical energy, comprising a stator (2) and a rotor (1), characterized by this? that a second stator (3) ? integrated with the first and has the rotor of the reversible electrodynamic system in common with the first stator, the two stators (2; 3) being arranged concentrically, one outside and one inside the rotor (1). 2) Energy accumulator as in 1), characterized by what? that each of the two stators (2; 3) can? be connected, independently of the other (3; 2) to the electricity grid or to an electric generator as its engine. 3) Accumulator as in 2), characterized by what? that the stators and rotor can be combined with each other through different types of circuitry. 4) Energy accumulator as in any previous claim, characterized by what? that the rotor (1) includes an additional mass (5) integral with it which increases its inertia. 5) Energy accumulator as in 4), characterized by what? that said mass (5) has an axis of symmetry that coincides with the axis (4) of rotation of the entire electrodynamic and inertial system. 6) Energy accumulator as in 4) or 5), characterized by what? That ? integrated by various oscillating mechanisms (6), coupled to the mass (5) integral with the rotor (1). 7) Energy accumulator as in 6), characterized by what? that said oscillating mechanisms (6) are made up of a housing (7), a spring (8) and an oscillating mass (9). 8) Energy accumulator as in 6) or 7), characterized by what? that the oscillating mechanisms (6) are coupled to the mass (5) in such a way that each compression axis of each spring (8) has a radial direction with respect to the rotor (1). 9) Energy accumulator as in any of the previous claims, characterized by what? which is operated in a vertical plane of rotation. 10) Energy accumulator as in any one of claims 6) to 9), characterized by what? that there are blocks and constraints on the mass (5) integral with the rotor (1) and/or on the oscillating mass (9).