The present invention relates to a method and to an apparatus for the disposal of photovoltaic panels.

Nowadays conventional photovoltaic panels are constituted substantially by an electrically insulating element protecting against atmospheric agents (arranged on the rear side of the panel), by photovoltaic cells (made of mono- or multi-crystalline silicon), by strings (which solder, in series and in pairs, the fronts and backs of adjacent cells), by ribbons which connect the strings in series, by two layers of encapsulating material (usually EVA) which enclose the cells and the strings front and rear, by a flat glass layer that encloses and protects the front side of the panel that faces the sun, and by a frame that encloses the perimeter of the panel.

Conventional panels are therefore constituted by a plurality of components which, structurally, can differ greatly from each other.

Conventional panels suffer a great drawback, which is the disposal thereof at the end of their life.

Given the diversity of the materials used, to date no solution is known which makes it possible to separate and reuse the individual components of the panel, apart from the glass which however must be separated in advance from the plastic material coupled thereto.

Such operation occurs by heating the glass to about 500°C: this entails the emission of toxic gases which must be treated in order to not be introduced into the environment, with consequent increase in costs.

The aim of the present invention is to solve the above mentioned technical problems and eliminate the drawbacks in the cited known art by devising a method and an apparatus for the disposal of photovoltaic panels which make it possible to achieve the separation and the reuse of the individual components of the panel.

Within this aim, an object of the invention is to provide a method and an apparatus in which the separation of the individual components of the panel occur without introducing harmful gases or fumes into the environment.

A further object is to provide a method and an apparatus that make it possible to separate the various components of the panel so that they can be reused immediately without having to undergo further processing.

A still further object is to provide a method and an apparatus that require a treatment time of the components which is contained in a few hours.

Another object is to provide a method and an apparatus that can work at temperatures below one hundred degrees centigrade.

Another object is to provide a method and an apparatus that require a very low energy consumption.

Another object is to provide a method and an apparatus that necessitate components that can usually be sourced on the market and which are low cost both to provide and maintain.

This aim and these and other objects which will become better apparent hereinafter are achieved by a method for the disposal of photovoltaic panels, which are constituted by an element protecting against atmospheric agents, by photovoltaic cells, by strings connected with ribbons, by two layers of encapsulating material, by a flat glass layer and by a frame, characterized in that it comprises the following steps:

- loading said photovoltaic panel, from which said frame has previously been removed, into a reactor;

- introducing a mixture based on acetone and ethylene into said reactor;

- hermetically closing said reactor;

- heating diathermic oil to a set temperature and introducing said oil into a pipe coil present in said reactor;

- maintaining said oil at a constant temperature and starting a process of separation of the materials contained in said reactor;

- cooling a condenser for the abatement of the hot vapors emitted by said reactor;

- control the pressure generated inside said reactor by way of a solenoid valve that opens and allows the discharge of said hot vapors which are directed into said condenser inside which they are abated and reconverted to said mixture;

- cooling said reactor and activating an aspiration device which, connected to a carbon filter/expansion vessel, to said condenser and to said reactor, creates the circuit that makes it possible to abate and filter said vapors;

- interrupting the cooling at the end of the chemical reaction inside said reactor and opening said reactor for the extraction of the separated materials at the end of the work cycle and the drying thereof.

Conveniently what is also claimed is an apparatus for the disposal of photovoltaic panels, which are constituted by an element protecting against atmospheric agents, by photovoltaic cells, by strings connected with ribbons, by two layers of encapsulating material, by a flat glass layer and by a frame, characterized in that it comprises:

- a reactor for containing said photovoltaic panel, from which said frame has previously been removed, which contains a mixture based on acetone and ethylene, said reactor being hermetically closeable;

- a basin for heating diathermic oil for sending, at a selected temperature and kept constant, into a pipe coil present in said reactor;

- a refrigeration assembly, connected to a condenser, for cooling said pipe coil present in said reactor;

- a filter/expansion tank, connected to said condenser, and, by way of an aspiration device, to a smokestack, for abating the hot vapors that are emitted by said reactor and in order to recover said mixture;

- a dryer adapted to eliminate the humidity from the separated materials in said reactor at the end of the work cycle and for recovering the residue of said mixture still present in said reactor;

- non-return val ves and automatic on/off valves.

Further characteristics and advantages of the invention will become better apparent from the detailed description of a particular, but not exclusive, embodiment, illustrated by way of non-limiting example in the accompanying drawing wherein Figure 1 is a schematic view of the apparatus.

In the embodiment illustrated, individual characteristics shown in relation to specific examples may in reality be interchanged with other, different characteristics, existing in other exemplary embodiments.

With reference to the figure, the reference numeral 1 generally designates an apparatus for the disposal of photovoltaic panels (not shown), of the type constituted by an element protecting against atmospheric agents, by photovoltaic cells, by strings connected with ribbons, by two layers of encapsulating material, by a flat glass layer and by a frame.

The method has a first step in which the photovoltaic panel, from which the frame has previously been removed, is placed inside a reactor 2; therefore the aluminum profiles are substantially separated from the photovoltaic cells.

The method then has a step in which, before or after the introduction of said photovoltaic panel, a mixture based on acetone and ethylene is placed inside the reactor 2.

The reactor 2 is then closed hermetically so that the substances present inside the reactor 2 are hermetically isolated from the outside environment.

The method then involves heating diathermic oil, which is contained in an adapted basin 3, to a set temperature which is kept constant; this oil is then introduced, by way of an adapted pump 4, into a pipe coil present inside the reactor 2.

Then the step of separation of the materials contained inside the reactor 2 begins.

During the step of separation of the metals, the method involves the activation of a refrigeration assembly 5 which comprises a fridge assembly that, connected to a condenser 6, carries out the cooling of the pipe coil present in the reactor 2.

The pressure generated inside the reactor 2 by raising the temperature of the mixture is controlled by way of a PLC system.

The part of such mixture present in the upper part of the reactor 2 is converted to vapor.

Control of the pressure generated inside the reactor 2 occurs by way of a solenoid valve 7 which opens and allows the discharge of the pressure (hot vapors).

The hot vapors are directed into the condenser 6 inside which they are abated and reconverted to the original chemical mixture, which can therefore be returned to the reactor 2 and therefore reused.

Once the process of separation of the metals is finished, the cycle of cooling the reactor 2 is begun by the refrigeration assembly 5 : the discharge valve 8 is opened, and an aspiration device 9 is activated which is connected to a carbon filter/expansion vessel 10 and to the condenser 6 and to the reactor 2, and which creates the circuit that makes it possible to abate and filter the vapors which are created during the chemical process.

The aspiration device 9 is connected to a smokestack 1 1.

Having reached a selected and adapted temperature for performing the opening of the reactor 2 and therefore to the moment at which the mixture has completed the chemical reaction and does not give off any substance, the cooling stops and the system for opening the reactor 2 is activated.

Only the aspiration device 9 remains switched on and this will be shut down at the end of the operations to extract the materials from the reactor 2.

A dryer 12 is also provided which is adapted to eliminate the humidity from the separated materials in the reactor 2 at the end of the work cycle and is adapted to achieve the recovery of the residue of the mixture still present in the reactor 2.

Obviously there are adapted non-return valves:

13, arranged connected to the reactor 2,

14, 15 arranged inside the filter 10,

16 for connection between the filter 10 and the condenser 6,

17 for connection between the dryer 12 and the condenser 6,

18 connected to the condenser 6 and automatic on/off valves 19, 20, 21 , 22,

and other valves 23, 24, 25, 26 which are interposed between the condenser 6, the reactor 2 and the refrigerator 5.

An air tank 27, an electrical switchboard 28 and adapted electrical connections 29 between the various components are also provided.

When the reactor 2 is opened, the materials extracted after the process are substantially constituted by glass, silicon, silver, and lead.

These materials, in a single agglomerate, are placed in the dryer 12 in order to allow the evaporation of the residual chemical mixture.

The vapors obtained are condensed and recovered in liquid (mixture) form which can then be reused.

Thus it has been found that the method and the apparatus fully achieve the intended aim and objects, since it is possible to dispose of photovoltaic panels and in the process recover up to the 95% of the disused materials (glass, silicon, silver, aluminum and other materials in smaller percentages).

Furthermore there is a simplicity and speed in the operations to separate and recover the materials regenerated; there is further a lack, during the process, of toxic and harmful fumes and/or dross. Finally, a reduced energy cost is necessary for the process. Obviously the invention is susceptible of numerous modifications and variations, all of which are within the scope of the appended claims.

Obviously the materials used as well as the dimensions of the individual components of the invention may be more relevant according to specific requirements.

The characteristics indicated above as advantageous, convenient or the like, may also be missing or be substituted by equivalent characteristics.

The content of Italian patent application no. MI2015A000006

( 102015902320293), the priority of which is claimed in the present application, is incorporated as a reference.

Where the technical features mentioned in any claim are followed by reference numerals and/or signs, those reference numerals and/or signs have been included for the sole purpose of increasing the intelligibility of the claims and accordingly, such reference numerals and/or signs do not have any limiting effect on the interpretation of each element identified by way of example by such reference numerals and/or signs.