AN ENGINE PROVIDED WITH A SYSTEM OF SOLAR PANELS TO WHICH THE LIGHT PRODUCED BY THE COMBUSTION FOR THE GENERATION OF

ELECTRIC CURRENT IS TRANSMITTED

Technical field

The present invention refers to the technical field relative to internal combustion engines.

In particular, the invention refers to an innovative technology that allows to recover luminous energy from the burst that takes place in the engine during the combustion .

Background art

Internal combustion engines for vehicles in general such as cars, motor-scooters, etc., have long been known. The working principle of an internal combustion engine is very simple and is based on the theoretical "Otto" cycle that foresees two isochoric thermo-dynamic phases and two adiabatic thermo-dynamic phases.

In a very schematic manner, the internal combustion engine foresees a combustion chamber formed by a cylinder having an inlet for a mixture of air-fuel, an outlet for the residues of the combustion and a spark plug that triggers a spark plug in the combustion chamber. The combustion chamber is therefore superiorly delimited by the walls of the cylinder and inferiorly by a piston mounted slidingly inside the cylinder and, in turn, connected to a piston rod connected, by the opposite end, to a rotatory axis. The alternate motion of the piston inside the cylinder is transformed in rotation of the rotatory axis through a transmission of the motion that takes place by means of the interposed piston rod. The alternate motion of the piston causes a rotation of the rotatory axis through the piston rod.

The cycle foresees the phases of:

Compression of the mixture injected in the cylinder; this phase is the first adiabatic phase without thermal exchange with the outside;

- The burst follows through a spark created by the spark plug, with an isochoric transformation at constant volume that causes an important rise of the pressure; - An adiabatic expansion follows with consequent translation of the cylinder towards the bottom that thus activates the piston rod;

- Return of the cylinder in initial position and therefore expulsion of the combusted gases;

- Retake of the cycle with a new burst following the injection of new air-fuel mixture.

This is naturally a basic working cycle which is however at the base of all the internal combustion engines .

In the current state of the art, technologies are present that allow energy saving and therefore energy recovery. The whole naturally translates , into fuel saving, and therefore into greater environmental respect and cost reduction for the user.

One of these technologies is for example described in

International patent application O2010061243 , wherein a fan is described placed at the front of the vehicle and which is kinematically connected to the engine. In this manner, during the advancement of the vehicle thanks to the engine, the fan is hit by the air flow and enters in action helping the engine itself, therefore reducing the consumption .

Nevertheless, this solutions is particularly complex from the mechanic point of view since it requires an integration of a mechanical structure that must be somehow collaborating with the engine. Moreover, the production of "auxiliary" engine, let's say, is linked to the motion of the vehicle and to its speed. If the engine is switched on, but the vehicle is still or in motion at reduced speed, it is not possible to obtain energy.

Other alternative solutions are already present in the market. For example, the classical internal combustion engine is put side by side to electric engines. In some vehicles the electric engine, even if for short path, can substitute the internal combustion one. Nevertheless, it is clear that the electric engine requires a periodic recharge and the recharge implies a production of current. In that sense, all that continues to reflect on the final user with costs to bear and, above all, as it is well known, the production of electric current has almost always a negative environmental impact.

Disclosure of invention

It is therefore the aim of the present invention to provide an engine, and a relative cylinder for an engine, that solve at least in part said technical inconveniences.

In particular, it is the aim of the present invention to provide an engine, and a relative cylinder for an engine, capable of significantly reducing the consumption and therefore of contributing to the reduction of costs and the reduction of pollution.

These and other aims are therefore reached with the present cylinder for an engine, as per claim 1.

Such a cylinder (1) forms a combustion chamber (50) and, in accordance with the invention, at least a photovoltaic surface (60) is further foreseen, arranged in such a way as to result to be irradiated by the light produced as a consequence of a combustion that takes place inside of such a combustion chamber (50) .

This solution solves easily all said technical problems .

In particular, the use of the solar panel allows to take advantage of the light emitted by the combustion for the production of current. Without such solar panels, the light would result unused and the production of electric energy, as discussed in the preamble of the background art, would be produced with complex mechanical systems or with recharge systems that are expensive for the user.

This solution, instead, in a simple and economical manner allows the production of electric current by simply taking advantage of the light generated by a combustion that takes place inside the engine during its normal use and making so that this light is precisely absorbed by specific photovoltaic panels.

The current is therefore produced in correspondence of the ignition of the vehicle, independently from the fact that it is still or in movement.

The electric current can then be stored . in specific batteries or can be used to feed electric devices present in the vehicle such as the alternator or even an auxiliary electric engine.

Advantageously, at least an optical fiber (10) can be foreseen, passing through said combustion chamber (50) in such a way as to be irradiated, in use, by the light emitted as a consequence of said combustion and wherein, further, said photovoltaic panel (60) is arranged externally to the combustion chamber in such a way as to be irradiated by the light transported by said optical fiber (10) in exit from the cylinder.

Advantageously, a passing hole (2) can be foreseen in the cylinder (1) through which the optical fiber (10) enters in the combustion chamber (50) and exits from the cylinder.

Advantageously, a transparent conduit (11) can be foreseen, arranged in such a way as to go through the cylinder (1), through the combustion chamber (50), the optical fiber passing inside said conduit (11).

Advantageously, said conduit (11) can be placed through the passing hole (2) .

Advantageously, the passing hole (2) can be threaded and the external surface of the conduit (11) presents a complementary thread that allows to screw the conduit (11) in the passing hole (2) .

Advantageously, in a variant of the invention, at least a photovoltaic surface can also be arranged directly inside the combustion chamber (50) .

Advantageously, in all the solutions described, the photovoltaic surface can be protected by a layer of transparent material resistant to heat, preferably glass brick.

Advantageously, the photovoltaic surface (60) produces electric current and is suitable for connecting to an external electric device-(70).

Advantageously, two photovoltaic surfaces (60', 60'') and a layer (200) of transparent material interposed between said two surfaces (60', 60'') can be foreseen, the optical fiber going through said layer (200) in such a way as to result comprised between said two photovoltaic surfaces (60' , 60' ' ) .

It is also described here the engine that foresees the type of cylinder described above.

In particular, an engine is described comprising at least a cylinder (1) that forms a combustion chamber (50) and wherein at least a photovoltaic surface (60) is foreseen, arranged in such a way as to result to be irradiated by the light produced as a consequence of a combustion that takes place inside the combustion chamber (50) .

Advantageously, at least an optical fiber (10) is foreseen, passing through said combustion chamber (50) in such a way as to be irradiated, in use, by the light emitted as a consequence of said combustion and wherein, further, said photovoltaic panel (60) is arranged externally to the combustion chamber in such a way as to be irradiated by the light transported by said optical fiber (10) in exit from the cylinder.

Advantageously, a passing hole (2) can be foreseen in the cylinder (1) through which the optical fiber (10) enters in the combustion chamber (50) and exits from the cylinder .

Advantageously, a transparent conduit (1) can be foreseen, arranged in such a way as to go through the cylinder (1) through the combustion chamber (50), the optical fiber passing inside said conduit (11).

Advantageously, the conduit (11) can be placed through the passing hole (2) .

Advantageously, the passing hole (2) can be threaded and the external surface of the conduit (11) presents a complementary thread that allows to screw the conduit (11) in the passing hole (2) .

Advantageously, the photovoltaic surface can be arranged directly inside the combustion chamber (50).

Advantageously, the at least one photovoltaic surface can be protected by a layer of transparent material resistant to heat, preferably glass brick.

Advantageously, the photovoltaic surface (60) produces electric current and is suitable for connecting to an external electric device (70) .

Advantageously, two photovoltaic surfaces (60', 60'') and a layer (200) of transparent material interposed between said two surfaces (60', 60'') can also be foreseen, the optical fiber passing through said layer (200) in such a way as to result to be comprised between said two photovoltaic surfaces (60' , 60'').

Brief description of drawings

Further features and advantages of the present invention will result clearer with the description that follows of some embodiments ,' made to illustrate but not to limit, with reference to the annexed drawings, wherein:

- Figure 1 shows schematically a cylinder 1 inside of which a piston 6 is placed slidingly and provided with a passing hole for an optical fiber;

- Figure 2 shows a top assembly view of more cylinders put side by side and gone through each one by an optical fiber;

- Figure 3 shows a detail of the optical fiber 10 which passes inside of a conduit 11 of containment of the transparent type;

- Figure 4 schematizes the phase of ignition through the spark off of the spark and the consequent explosion which frees the light that is captured by- the optical fiber passing through the combustion chamber 50;

- Figure 5 shows the optical fiber connected to a solar panel 60 installed in the vehicle and whose electric current produced can be used for many uses in the vehicle, for example, the activation of the alternator and the activation of an electric engine of aid to the internal combustion engine; - Figure 6 shows, last, a constructive solution with two overlapped panels and having a layer of transparent material interposed into which the optical fibers pass.

Description of some preferred embodiments

Figure 1 shows a cylinder of an internal combustion engine in accordance with the invention.

The cylinder 1 forms inside of it a combustion chamber 50, inside of which a piston 6 is slidingly arranged, hinged to a piston rod 7. The alternate sliding motion of the piston 6 activates the piston rod that transforms this alternate motion in a rotatory motion for the axis to which the piston rod itself results to be connected.

Figure 1, just for clarity purposes, shows with a thin dotted line the piston 6, the piston rod 7 and the walls that delimit the cylinder and in respect of which the piston 6 slides.

Always in figure 1 the inlets 4 (IN) are. shown for the air-fuel mixture and the outlet 3 (OUT) for the expulsion of the combusted gases. It is then shown the spark plug 5 that triggers the ignition, as it is well known in the state of the art.

In accordance with the invention, figure 1 shows an opening 2 of passage in the cylinder and that allows a passage from part to part of an optical fiber 10.

The opening is placed above the superior dead point, that is in a position that is not reached by the piston during its working cycle.

As shown in figure 3, a conduit 11 is foreseen that serves for the containment of the optical fiber in its passage through the cylinder.

The conduit 11 can be of any shape but, preferably, of the cylindrical type.

The conduit is realized in a material transparent to light and such as to resist to the temperatures inside of a cylinder for internal combustion engine.

A possible idoneous material for these purposes can for example be the glass brick.

The conduit 11 therefore presents externally a thread in such a way as to be screwed inside the passing hole 2, in turn provided with complementary thread.

The hole 2 of passage is naturally placed in axis with a second hole to allow, from the opposite part of the cylinder, the exit of the conduit 11 and therefore the passage of the optical fiber.

The top view of figure 2 highlights well an assembly of three cylinders 1 and the conduit 11 passing in the cylinder from part to part with the optical fiber that passes inside of it.

As it is then schematized in figure 5, the optical fiber results communicating with a system of photovoltaic paneling 60 in such a way as to irradiate it with the light that it transports.

In that sense, the optical fiber is a physical channel to transport the light produced by the combustion inside of the cylinder to take it externally to an idoneous system of solar panels.

Solar panels are well known in the state of the art and are constituted by photovoltaic cells which, when irradiated by light, produce electric current.

Being well known in the state of the art, solar panels will not be further described in detail here.

The electric current produced by the system can be useful for many purposes inside of the vehicle where it is installed .

For example, figure 5 schematizes an electric engine 70 which is fed by the current produced by the photovoltaic panel at each internal combustion cycle and therefore that can in turn be used as an aid to the internal combustion engine or as reserve electric engine.

Alternatively, for example, the current produced could be stored in a battery to be re-used subsequently or to feed an alternator.

Going on with the structural description of the invention, figure 6 shows a preferred embodiment of the invention .

In this case, a superior photovoltaic panel 60' and an inferior photovoltaic panel 60' ' are foreseen. Interposed between said two photovoltaic panels a layer 200 of transparent material is foreseen, which allows the passage of the optical fibers 100.

The layer 200 interposed can for example be in glass-ceramic or in a transparent material of the plexiglass type.

This solution has the advantage that the light transported is used almost completely since two opposed photovoltaic surfaces are easily irradiated.

A contour frame can be foreseen in a highly reflecting material, such as a mirror, so as to eliminate the lateral losses directed laterally from the optical fibers and make that these lateral luminous beams are again directed towards the panels. In this manner, the absorption of the light by the panels is maximized.

The photovoltaic surfaces can be positioned in any convenient point inside the vehicle. For example, the solution of figure 6 lends itself well to an installation below the hood of the vehicle where precisely the engine compartment is arranged.

With reference to figure 4, in use, the functioning is the following.

The figure shows the passage of the optical fiber through the channel formed by the conduit 11 in a material transparent to light. The conduit 11 passes from part to part of the cylinder through the holes 2 in axis.

At each functioning cycle of the engine, that is every time the trigger of a spark 100 from the spark plug takes place and therefore the consequent explosion, the optical fiber is irradiated by the light generated from the burst and will transport this light to the photovoltaic surface/s, consequently irradiating them.

The photovoltaic surfaces, in turn, will be capable of producing electric current usable for the most varied purposes .

Just as a way of example, not limiting, some examples are mentioned below.

A four-cylinder engine working at a regime of 4.000 r/min produces 16.000 luminous beams/min that are transported and that irradiate the photovoltaic surfaces. On the basis of the size of the engine and of the photovoltaic panels used, it is obvious that a huge quantity of energy can be produced.

In a variant the conduit 11 could be integral to the cylinder but the screwed solution has the advantage of allowing an easy disassembly both for the maintenance and for the periodic cleaning. Dirt residues could obscure the conduits themselves and therefore reduce the quantity of light that hits the optical fibers themselves. The conduit 11 could also be inserted by mechanical interference.

In a further variant of the invention, the passage of the optical fibers could take place without the aid of the conduits 11 if it is possible to select a type of fiber capable of resisting to the internal temperatures.

In a further variant of the invention, it could be possible to foresee the application of a photovoltaic surface directly in the combustion chamber. For example, photovoltaic micro-panels can be applied directly in the walls forming the combustion chamber. Alternatively, a photovoltaic varnish can be used, applied on the internal wall of the combustion chamber. These solutions would require the protection of the panel with a transparent layer, for example of glass brick, to maintain integral the panel despite the high temperatures.

This solution has the advantage of not requiring the use of optical fibers but, obviously, the operation of cleaning of the photovoltaic panels results extremely complex, operation that is necessarily required to ensure that the absorption surface of the light is always the maximum. It is obvious that this solution, although possible, would require a periodical disassembly of the cylinders of the engine. Moreover, the size of the combustion chamber is minimum and therefore also the internal photovoltaic surface that can be placed is really minimum .

The solution with the optical fibers, instead, allows to place the panels in points of easy access for cleaning, in addition to allow the realization of photovoltaic surfaces not bound anymore to the restricted size of a combustion chamber formed by a classical cylinder.

Although the invention has been described with particular reference to the internal combustion engine, it is obvious that the same results equally applicable to all those engines in which an explosion takes place, not necessarily triggered by a spark plug as in the internal combustion engine described.

In that sense, for example, the same technology can without problems be applied to the diesel engine in which the explosion is not obtained through a spark generated by the spark plug but, rather, through a high value of pressure with which the piston compresses the mixture of air-diesel inside of the combustion chamber.

It is obvious that this technology lends itself well to any type of engine with cylinders in which a combustion takes place and therefore an explosion with emission of light (therefore also LPG or methane) .

Obviously, the production and selling of the single cylinder as described is possible, to then mount it on a specific engine, or the integral realization of an engine is possible that is born already with said cylinders as described .