IT201900000563A1 - Process for the production of oxyhydrogen. - Google Patents

Description

DESCRIPTION of the industrial invention entitled: "Process for the production of oxyhydrogen"

DESCRIPTION

Technical field

The present invention relates, in general, to the sector of electrolytic cells; in particular, the invention refers to a process for the production of oxyhydrogen through at least two electrolytic cells.

Known technique

The use of electrolytic cells for the production of oxyhydrogen is known, which exploit an electrolysis process obtained by immersing electrically charged metal plates in a suitable solution.

In known processes for the production of oxyhydrogen, the plants for the production of oxyhydrogen gas comprise at least one electrolytic cell which is powered for the entire period in which the production of oxyhydrogen is required.

Such a control logic has considerable disadvantages. In particular, a disadvantage concerns the poor relationship between the consumption of electricity and the production of oxyhydrogen gas. For example, when such systems for the production of oxyhydrogen gas are installed on board a vehicle, they will be powered mainly by the vehicle's battery. Disadvantageously, if the electrolytic cell has to be powered for the entire period in which the production of oxyhydrogen is required, the vehicle battery will be discharged in a short period of operation, causing considerable inconvenience for the vehicle owner. In particular, this disadvantage is of primary importance since, when the vehicle battery were to run down, it would no longer be possible to produce oxyhydrogen and the operation of the vehicle itself would be compromised.

Summary of the invention

An object of the present invention is to obviate the aforementioned problems.

To obtain this result, a process for the production of oxyhydrogen is provided which has the advantage of allowing an optimization of the relationship between the consumption of electrical energy and the production of oxyhydrogen gas. An electronic control unit is also provided.

The above and other objects and advantages are achieved, according to an aspect of the invention, by a process for the production of oxyhydrogen having the characteristics defined in claim 1 and by an electronic control unit having the characteristics defined in claim 6. Preferred embodiments of the The invention are defined in the dependent claims.

Brief description of the drawings

The functional and structural characteristics of some preferred embodiments of a process for the production of oxyhydrogen and of an electronic control unit according to the invention will now be described. Reference is made to the attached drawings, in which:

Figure 1 illustrates two graphs in which the time intervals in which the first electrolytic cell is powered and in which the second electrolytic cell is powered are respectively illustrated; Figure 2 shows two graphs in which the time intervals in which the first electrolytic cell is powered and in which the second electrolytic cell is powered, in which the duration of the first time interval of feeding of the first cell is varied in at least one iteration;

- Figure 3 illustrates two graphs in which the time intervals in which the first electrolytic cell is powered and in which the second electrolytic cell is powered are respectively illustrated, in which for a given number of iterations the duration of the first time interval is varied in each iteration;

- Figure 4 illustrates two graphs in which the time intervals in which the first electrolytic cell is powered and in which the second electrolytic cell is powered, are respectively illustrated, in which between the first time interval and the second time interval there is a third time interval in which both the first electrolytic cell and the second electrolytic cell are partially powered; And

Figure 5 illustrates a graph which relates the energy used to power an electrolytic cell with the production of hydrogen by said electrolytic cell.

Detailed description

Before explaining in detail a plurality of embodiments of the invention, it should be clarified that the invention is not limited in its application to the construction details and configuration of the components presented in the following description or illustrated in the drawings. The invention is able to assume other forms of embodiment and to be practiced or implemented in practically different ways. It must also be understood that the phraseology and terminology are for descriptive purposes and should not be construed as limiting.

Referring by way of example to Figure 1, in a first embodiment, the process for the production of oxyhydrogen by means of at least a first electrolytic cell and a second electrolytic cell comprises the following steps.

In step a, in a first time interval t1, the first electrolytic cell is fed and the second electrolytic cell is not fed.

In a further step b, in a second time interval t2, the first electrolytic cell is not powered and the second electrolytic cell is powered.

In a still further step, the two steps a and b previously described are iterated cyclically.

Advantageously, as can be seen in Figure 5, an electrolytic cell is capable of accumulating electrical energy capable of producing oxyhydrogen gas even during the feeding phase with decreasing frequency, that is, during the phase of less use of electrical energy.

This alternation allows two cells to be powered with alternating frequencies with set peak power and cleaning times, "woshing", i.e. zero power supply, guaranteeing a constant power supply that nullifies the overload stress of a vehicle alternator.

In particular, the cleaning phase, i.e. the cleaning of the plates which leads to the emptying and subsequent filling of the cell with the electrolytic solution, ensures the optimization of the production of oxyhydrogen and at the same time nullifies the undesired phase of complete absence of power to the source electrolytic cell. of imbalances and drops in gas production.

Clearly, by indicating that the process is applied for at least a first electrolytic cell and a second electrolytic cell, it is also possible to apply the process analogously to a first group of electrolytic cells and to a second group of electrolytic cells. In particular, the first group of electrolytic cells will be controlled in the same way as the first electrolytic cell, and the second group of electrolytic cells will be controlled in the same way as the second electrolytic cell.

In a further aspect, the duration of the first time interval t1 and the duration of the second time interval t2 are such as not to allow the first electrolytic cell and the second electrolytic cell to reach a total condition of inertia of the cell.

The duration of the first time interval t1 and the duration of the second time interval t2 can be kept constant in each iteration of steps a and b, as illustrated in Figure 1.

Or, the duration of the first time interval t1 and / or the duration of the second time interval t2 can / can be varied / varied in at least one iteration of steps a and b, as illustrated in Figure 2.

For example, the iteration frequency of steps a and b can be a frequency comprised between 1 and 159 kHz in a square wave with subsequent decreasing phase in modular and continuous form. An exemplary set of useful frequencies may include, for example, 1.2412kHz, 2.4843kHz, 4.9687kHz, 9.9375kHz, 19.875kHz, 39.75kHz, 79.5kHz, 159kHz.

Furthermore, for a given number of consecutive iterations of steps a and b, the duration of the first time interval t1 and / or the duration of the second time interval t2 can / can be varied / varied in each iteration, as illustrated in Figure 3.

For example, the frequencies useful for obtaining an optimal result of the electrolytic production of oxyhydrogen, according to the specific characteristics of both the electrolytic cell and the entire plant, provide for a cycle of use of 8 (eight) distinct multiple-sequence frequencies with a maximum relative to the minimum frequency not higher than 1.2412874 kHz.

The duration of the first time interval t1 and / or the duration of the second time interval t2 can / can be varied according to at least one of the following factors:

- the variation of the vehicle acceleration on the 3 axes x, y, z;

- the number of engine revolutions of the vehicle;

- magnetic and / or pressure sensor for C.T.

In a further aspect of the invention, with reference to Figure 4, between the first time interval t1 and the second time interval t2 there may be a third time interval t3 in which both the first electrolytic cell and the second electrolytic cell are partially powered. Partially powered means that both the first electrolytic cell and the second electrolytic cell are not powered with the maximum available energy, but are powered, for example, with only half of the available energy.

This alternation allows to insert an average feeding phase between the peak feeding phase and the cleaning feeding phase, "woshing", described above. This has the advantage of producing oxyhydrogen gas with reduced energy use. The "woshing" cleaning guarantees maximum gas production over time. Furthermore, the alternation and "woshing" times can be freely extended and / or contracted according to the RPM and accelerations or thermal power required (for boilers and / or C.T. thermal power stations).

The procedure can be implemented in an electronic control unit, particularly designed to be installed on board the vehicle or in a boiler or in a C.T. thermal power station.

For example, the control unit can be based on a microprocessor or microcontroller system.

Furthermore, the control unit can comprise an accelerometric sensor arranged to provide the projection of the acceleration imposed on the vehicle on three axes x, y, z. In this case, the offset due to the earth's gravity can be set at each reading and therefore only the acceleration of the vehicle in module and phase can be determined.

In other words, the accelerometric sensor can be arranged to determine the acceleration of the vehicle on which the electronic control unit is installed, so as to determine a vehicle movement situation between possible different vehicle movement situations. The different movement situations can be, for example, acceleration in plane, ascent, descent, and it is therefore possible to modulate the duration of the first time interval t1 and / or the duration of the second time interval t2 with different strategies.

By integrating the data it is then possible to obtain the vehicle speed information and also use this quantity to modulate the duration of the first time interval t1 and / or the duration of the second time interval t2 with which the cells are controlled.

The type of electrolytic cell controlled by the process of the present invention can for example be an electrolytic cell for the production of oxyhydrogen gas comprising a pair of end plates or plates, between which a plurality of intermediate plates are interposed, mutually facing each other and able to be immersed at least in part in an aqueous solution to induce an electrolysis process.

These intermediate plates can comprise at least one pair of active intermediate plates, located in the most proximal positions with respect to the end plates and suitable for being directly electrically powered (by means of an external electrical circuit, not shown), and one or more neutral intermediate plates, interposed between these intermediate plates active and not connected to an electrical supply.

The active intermediate plates can be only two, in which case one would be the cathode and the other the anode, or three (or more), in which the outermost intermediate plates (adjacent to the end plates) act as cathodes, while the intermediate plate in central position acts as an anode.

Between the intermediate plates are interposed gaskets designed to define a watertight volume on the perimeter between two facing intermediate plates. The volume thus defined can therefore be at least partially occupied by the electrolytic solution and, by virtue of the latter's contact with the intermediate plates, there will be production of oxyhydrogen, which will tend to collect towards the top of the volume (in which the oxydrogen is indicated with the words "HHO").

Furthermore, at least one of the intermediate plates has a distributed perforation, formed by a plurality of holes passing through said intermediate plate. Conveniently, all intermediate plates are provided with a distributed perforation.

Various aspects and embodiments of a process for the production of oxyhydrogen and of an electronic control unit according to the invention have been described. It is understood that each embodiment can be combined with any other embodiment. Furthermore, the invention is not limited to the embodiments described, but may be varied within the scope defined by the attached claims.

Claims (8)

CLAIMS 1. Process for the production of oxyhydrogen by means of at least a first electrolytic cell and a second electrolytic cell comprising the steps of: a) in a first time interval (t1) powering the first electrolytic cell and not powering the second electrolytic cell; b) in a second time interval (t2) not to power the first electrolytic cell and to power the second electrolytic cell; And c) cyclically iterate steps a and b; the duration of the first time interval (t1) and the duration of the second time interval (t2) being such as not to allow the first electrolytic cell and the second electrolytic cell to reach a total condition of inertia of the cell. Process for the production of oxyhydrogen according to claim 1, wherein the duration of the first time interval (t1) and the duration of the second time interval (t2) are kept constant in each iteration of steps a and b. Process for the production of oxyhydrogen according to claim 1, wherein the duration of the first time interval (t1) and / or the duration of the second time interval (t2) is / are varied in at least one iteration of the steps a and b. 4. Process for the production of oxyhydrogen according to claim 1, wherein for a given number of iterations of consecutive steps a and b, the duration of the first time interval (t1) and / or the duration of the second time interval (t2) is varied / are varied in each iteration. Process for the production of oxyhydrogen according to any one of the preceding claims, wherein the process further comprises the following step: c) in a third time interval (t3), between the first time interval (t1) and the second time interval (t2), partially powering the first electrolytic cell and the second electrolytic cell; step c being iterated cyclically between steps a and b. 6. Electronic control unit, particularly designed to be installed on a vehicle or in a boiler or in a thermal power station, and configured to carry out a method according to any one of the preceding claims. Electronic control unit according to claim 6, comprising an accelerometric sensor arranged to determine the acceleration of the vehicle on which the electronic control unit is installed, so as to determine a movement situation of the vehicle. Electronic control unit according to claim 7, wherein the duration of the first time interval (t1) and / or the duration of the second time interval (t2) is varied as a function of the determined vehicle movement situation.