IT9003570A1 - ELECTROLYTIC EQUIPMENT FOR THE PRODUCTION OF GAS. - Google Patents

Description

D E S C R I Z I O N E D E L T R O V A T O

The present invention relates to an electrolytic apparatus for the production of gas, of the type comprising an electrolytic cell containing an electrolytic substance from which to obtain said gases, said electrolytic cell being equipped with a plurality of planar polarizable electrodes and electrically placed in series inside said cell electrolytic, from whose walls they are electrically insulated, said planar electrodes being arranged so as to divide said electrolytic cell into a plurality of adjacent elementary cells.

As is known, some chemical substances in the molten state, or in liquid solution, when crossed by an electric current, usually continuous, inside an electrolytic cell, give rise, on the electrodes of the cell, to the development of gaseous substances which they can be collected and conveyed outside for further uses. In particular, if the substance subjected to electrolysis consists of water or sodium, potassium, lithium hydroxides and / or their mixtures, both in the pure state and in aqueous solution, on the positively charged electrode (anode) it is possible to produce molecular oxygen in the form of gas, while on the negatively charged electrode (cathode) there is simultaneous development of hydrogen.

In general, it is also known that for each characteristic chemical composition of the electrolytic substance there is a certain value of the electric potential called the thermodynamic decomposition (or decomposition) potential, below which the electrolytic process would strongly decline in efficiency or even would not start. On the other hand, the process accelerates as this electric potential increases, but it is necessary to respect higher limits, imposed by the corresponding increase in temperature, which instead decreases the efficiency. In water, for example, this thermodynamic decomposition potential takes on a theoretical value of about 1.23 Volts. In order to avoid having to lower the electric output voltage of the normal electric generators used in such applications to these values, the usual electrolytic apparatuses provide several elementary cells in series. In particular, they provide an electrolytic cell open at the top, so as to present a free surface for the electrolytic substance, divided into a multiplicity of elementary cells, not communicating with each other, arranged in series one next to the other and physically made by insertion , in the electrolytic cell itself, of a plurality of metal electrodes electrically insulated from the walls of the cell and shaped in such a way as to constitute vertical dividing septa parallel arranged and lapped bilaterally, except obviously those at the ends, by the electrolytic substance contained in the cell. The electrodes are normally polarized by simply connecting the extreme ones with a current generator. In this way, all the electrodes between them polarize, according to a known phenomenon of polarization characteristic of metals, so as to assume: on one side, positive potential and on the opposite side, negative potential, ultimately acting at the same time as an anode for an elementary cell and as a cathode for the adjacent unit cell that shares the same electrode.

During the electrolytic process, in the interface area between the electrode and the electrolytic substance, gases develop which, bubbling through the electrolytic substance, rise towards the upper part of the cell where, captured by a collection bell, positioned above the electrodes , are conveyed towards the outside of the equipment.

This equipment has highlighted significant functional drawbacks resulting from the fact that the individual elementary cells, and particularly those more central and distant from the end cells, cannot effectively disperse the heat, normally produced during the electrolytic process, consequently causing a decline in operating efficiency. the more accentuated the higher the temperature reached.

Furthermore, since the electrolytic substance contained in the individual elementary cells decreases its level during the evolution of the electrolytic process, the aforementioned apparatus has, for each elementary cell, an electrolyte level sensor suitable for controlling the activation of suitable actuator means for the automatic reintegration of the quantity of electrolytic substance consumed in the single elementary cells.

This equipment, in practical implementation, has therefore proved to be not very reliable and excessively complex, also due to the general constructive complexity mainly attributable both to the means for capturing and conveying the gases, and to the need to provide level sensors on each elementary cell. and ducts for replenishing the consumed electrolytic substance.

The aim of the present invention, as characterized by the claims, is therefore to eliminate the aforementioned drawbacks. The invention, as it is characterized by the claims, solves the problem of providing an electrolytic apparatus for the production of gas which, despite its extreme constructive simplicity, allows adequate refrigeration of the entire electrolytic cell and simultaneous easy recovery of the gas.

The electrodes are in fact provided with at least one transverse hole, made in the area lapped by the electrolytic substance, able to make adjacent elementary cells intercommunicate so as to allow a circulation of electrolytic substance (and gas) between them which is suitable for refrigerating the entire electrolytic cell. .

The equipment also advantageously provides a gas separator, located downstream of the electrolytic cell, from the top of which the gases are withdrawn to be conveyed to an external user and from the base of which the electrolytic substance is instead taken to be re-introduced internally. to the electrolytic cell.

The advantages obtained by means of the present invention essentially consist in the fact that the elementary cells, intercommunicating with each other, are all cooled by the circulation of the electrolytic substance regardless of their position in the overall electrolytic cell.

Furthermore, the presence of the communication holes between one elementary cell and the other allows to use a single level sensor for all the elementary cells, also simplifying the construction of the gas conveyor ducts.

Ultimately, the invention is distinguished by a higher functional efficiency of the electrolytic cell consequent to the refrigeration of the elementary cells and by a lower constructive complexity of the entire apparatus.

The invention is set out in more detail below with the help of the drawings which represent a purely exemplary and non-limiting example of execution in which:

Figure 1 illustrates an overall system diagram of the apparatus made according to the invention;

Figure 2 illustrates, on an enlarged scale, a partial section of the electrolytic cell with which the apparatus is equipped;

Figure 3 illustrates a cross section, made according to line III-III, of the electrolytic cell of Figure 2.

With reference to Figure 1, it can be seen that the invention substantially consists of an electrolytic apparatus (1) for the production of gas, preferably hydrogen and oxygen, starting from an electrolytic substance (6).

The electrolytic apparatus (1) comprises a cylindrical electrolytic cell (2), internally provided with a plurality of horizontal, metallic, planar electrodes (3), vertically stacked for the purposes that will be further clarified below, and supported by rings (7) in dielectric material interposed so as to identify in combination with the walls (4) of the cell (2)

electrolytic.

The planar electrodes (3) are made of stainless steel or steel externally coated with platinum or palladium in order to resist corrosion due to contact with the electrolytic substance (6) and are completely isolated, electrically, both from each other by the aforementioned rings ( 7) in dielectric material, and by the walls (4) of the electrolytic cell (2) which are possibly internally coated with a layer (71) of dielectric material, as shown in Figure 2.

The planar end electrodes (3) of the electrolytic cell (2) are electrically connected to a preferentially continuous current generator (8) and polarize all the planar electrodes (3) intermediate to them by a known phenomenon of electric induction.

Since the elementary cells (5) are ultimately electrically connected in series, they are always present inside the electrolytic cell (2) in such a number as to determine, among the planar electrodes (3) relating to a single elementary cell (5), a voltage drop at least equal to the thermodynamic decomposition potential of the electrolytic substance (6).

The most important feature of the invention consists in the fact that the planar electrodes (3) (see Figures 2 and 3) are also provided with at least one hole (9), made in an area lapped by the electrolytic substance (6) and able to communicate between them all the elementary cells (5) of the electrolytic cell (2) so as to allow between them a circulation of fluid consisting of the electrolytic substance (6), but also a corresponding circulation, which can also be natural, of the gases produced on the electrodes (3) planar during the electrical connection of the electrodes (3) planar to the generator (8) of current.

This fluid, moved preferably, but not necessarily by suitable means (10) actuating a forced circulation, through all the elementary cells (5) drags the gases developed on the planar electrodes (3) towards the outside of the electrolytic cell (2), cooling at the same time all the elementary cells (5). It is convenient for this circulation to take place in the natural sense, that is, from the bottom upwards.

In order to make the refrigeration of the elementary cells (5) more effective, the planar electrodes (3) are arranged inside the electrolytic cell (E) so as to have linearly offset holes (9), determining a consequent labyrinth-like curvilinear path of the substance. (6) electrolytic suitable to determine a more intense mixing of this inside the elementary cells (5).

Downstream of the electrolytic cell (2), the electrolytic equipment (1) provides a vertical gas separator (11), provided with a domed top (13), connected to the electrolytic cell (2) by means of an interposed fluid conveyor (12) outgoing from the electrolytic cell (E) itself.

Inside the vertical separator (11) the gases contained in the fluid received by the electrolytic cell (2) are separated by the difference in density from the electrolytic substance (6), collecting at the domed top (13), while the electrolytic substance (6) is has the vertical separator (11) in correspondence with the lower part (14).

The vertical separator (11) is also provided with a single sensor (15) for the level of the electrolytic substance (6) capable of ensuring, for the reasons that will be more evident later, the complete filling of the electrolytic cell (2) and consequently of all its elementary component cells (5).

The electrolytic apparatus (1) also comprises a cooler (16) of the electrolytic substance (6) arranged downstream of the vertical separator (11) from which it receives the electrolytic substance (6) through a conveyor tube (121) to refrigerate it prior to its reintroduction in the electrolytic cell (2) in turn arranged downstream of the cooler (16).

Preferably, the aforementioned means (10) for the forced circulation of the fluid circulating inside the elementary cells (5) are made by a pump arranged on the conveyor (121) of the electrolytic substance (6) downstream of the vertical separator (11).

The electrolytic (1) equipment also comprises a single circuit (17) replenishing the electrolytic substance (6) consumed during the gas production process. This circuit (17) interconnected with the vertical separator (11) so as to restore the level of the electrolytic substance (6) by activating a pump (18) with the consent of the sensor (15).

The invention thus conceived is susceptible of numerous modifications and variations and a multiplicity of uses, all of which are within the scope of the inventive concept.

In fact, it can be observed that from the domed top (13) of the vertical separator (11) it is possible to withdraw gases through conventional means (25), for example in the case in which the electrolytic substance (6) is water, a gaseous mixture of hydrogen and oxygen in stoichiometric ratio and at atmospheric pressure which can be conveyed and used as such on a generic user (19) who, in the specific case, could be constituted by a torch (191) for oxyhydrogen welding. In this case, the electrolytic apparatus (1) according to the invention makes it possible to advantageously arrange on the user (19) and on the torch (191), a mixture of hydrogen and oxygen gas which, compared to traditional oxyhydrogen welding systems, has the advantage of never assume a physical-chemical state such as to induce explosive reactions, as it can therefore be used without the need for special safety devices.

Furthermore, the electrolytic equipment (1) can be used as a continuous producer of hydrogen and oxygen gas to be used for the exact duration of the welding process, avoiding having to resort to the need for bulky and dangerous pressurized gas storage containers normally used in welding. oxyhydrogen.

Another use of the electrolytic apparatus (1) according to the invention could be thought feasible as a low-cost producer of the same hydrogen and oxygen gas which are accumulated in the aforementioned storage containers.

In this case, it is sufficient to take, as shown in Figure 1, the mixed gases from the domed top (13) of the vertical separator (11), conveying them preliminarily to a molecular separator (20), arranged downstream of the means (25) of sampling, inside which they are separated and sent to separate storage tanks not shown in the figure because they do not interest the invention.

It should be noted that in this case, compared to the traditional systems used for this production, the invention allows an enormous simplification of the plant complexity, allowing advantageously to eliminate the complex and expensive gas compression apparatus present in the aforementioned plants.

In this case, in fact, it is the electrolytic cell (2) itself which behaves as a whole as a fluid pump able to pressurize the entire electrolytic apparatus (1). Consequently, all the components of the latter should, in such use, be constructed to withstand the pressure.

In particular, the electrolytic cell (2) should provide inside the rings (7) in dielectric material corresponding reinforcing rings (21) made for example in Teflon or materials with similar characteristics capable of giving the electrolytic cell (2) the necessary mechanical resistance to pressurization of the elementary cells (5).

All the details of the electrolytic apparatus (1) according to the invention can obviously be replaced by technically equivalent elements.

In this regard, it should be noted that if the pump (18) was operated manually, the level sensor (15) could be identified by a simple optical indicator of the level of the electrolytic substance (6) present inside the separator ( 11) vertical.

If, on the other hand, one wishes to make the pump (16) operation automatic, then it would be necessary to have on the vertical separator (11), as indicated in the same figure 1, a sensor (151) able to operate directly on the control circuit of the pump (18 ) when the level of the electrolytic substance (6) falls below the full filling value of the electrolytic cell (2).

In practice, modifications and / or improvements are obviously possible, in any case falling within the scope of the following claims.

Claims (15)

R I V E N D I C A Z I O N I Electrolytic apparatus for the production of gas, of the type comprising an electrolytic cell (2) containing an electrolytic substance (6) from which to obtain said gases, said electrolytic cell (2) being equipped with a plurality of polarizable flat electrodes (3) placed electrically in series inside said electrolytic cell (2), from whose walls (4) they are electrically insulated, said planar electrodes (3) being arranged so as to divide said electrolytic cell (2) into a plurality of adjacent elementary cells (5) , said electrolytic apparatus (1) being characterized by the fact that said planar electrodes (3) are provided with at least one hole (9), made in an area lapped by said electrolytic substance (6), suitable for making all said cells ( 5) elementary so as to allow a circulation of fluid between them, consisting of at least said electrolytic substance (6), suitable for cooling said electrolytic cell (2). Apparatus according to claim 1, characterized in that it comprises a single sensor (15) for the level of said electrolytic substance (6) for all said elementary cells (5). Apparatus according to claim 1, characterized in that it comprises a vertical gas separator (11) arranged downstream of said electrolytic cell (2) and interconnected to it by means of a conveyor (12) of said fluid leaving said electrolytic cell (2) , said vertical separator (11) being able to allow the gases contained inside said fluid to separate from said electrolytic substance (6) by density difference. Apparatus according to claim 3, characterized in that it comprises a cooler (16) of said electrolytic substance (6), arranged downstream of said vertical separator (11), from which it receives said electrolytic substance (6) so as to refrigerate it prior to its introduction into said electrolytic cell (2). Apparatus according to claim 3, characterized in that it comprises a single sensor (15) for the level of said electrolytic substance (6), located externally to the electrolytic cell (2) and in correspondence with said vertical separator (11). Apparatus according to claim 1, characterized in that said planar electrodes (3) are arranged horizontally and are vertically stacked inside said electrolytic cell (2). said planar electrodes (3) being supported by rings made of dielectric material interposed with them and able to distance them from each other, delimiting, in combination with the walls (4) of said electrolytic cell (2), said elementary cells (5). 7. Apparatus according to claim 6, characterized in that said electrolytic cell (2) has, inside said rings (7) made of dielectric material, corresponding reinforcing rings (SI) adapted to allow said electrolytic cell (2) to resist the pressurization. Apparatus according to claim 1, characterized in that it comprises means (10) for actuating the forced circulation of said fluid between said elementary cells (5). Apparatus according to claim 8, characterized in that said actuator means (10) consist of a pump (18). Apparatus according to claim 3, characterized in that a molecular separator (20) for said gases is provided downstream of said vertical separator (11), 11. Apparatus according to claim 1, characterized in that it comprises a single circuit (17) replenished with said electrolytic substance (6) consumed inside said electrolytic cell (2). Apparatus according to claim 1, characterized in that said holes (9) are mutually offset in such a way as to determine for said fluid a curvilinear path between said elementary cells (5). Apparatus according to claim 1, characterized in that said electrolytic substance (6) is water. Apparatus according to claim 5, characterized in that said elementary cells (5) are in such a number as to determine, between the relative planar electrodes (3), a potential drop equal to the thermodynamic decomposition potential of said electrolytic substance (6). 15. Apparatus according to the preceding claims and according to what is described and illustrated with reference to the figures of the accompanying drawings and for the aforementioned purposes.