ITPI20110096A1 - "A WATER DESALIFICATION DEVICE" - Google Patents

Description

Description accompanying the patent application for industrial invention entitled:

A WATER DESALIFICATION DEVICE

Scope of the invention

The present invention relates to the technical sector relating to the machinery, and relative method, used to carry out the desalination of water.

Brief notes on the known art

A recent cosmological physical theory is now known which includes among its direct consequences the possibility of using a new source of energy, the so-called "byuon" theory. This theory is essentially based on the observation of a marginal anisotropy of physical space, which is associated with a cosmological vector potential Ag having the dimensions of the vector potential of a magnetic field.

This theory is for example explained in the publication "La Trama Unvelata", Ed. Polistampa, Florence, 2009, for example in chapter 1 in "Fundamental postulates of the Byuon Theory".

As for example described in chapter 3, always of the same publication, it is possible to obtain the generation of energy, in particular heat, under certain conditions by exploiting the principles of this theory.

The basis of the Byuon theory is constituted by the assumption, confirmed by experimental observations, of a marginal global anisotropy of physical space, in turn linked to a new fundamental vector constant, the cosmological vector potential Ag, having the dimensions of the vector potential of a field magnetic and the following coordinates in the second equatorial system: right ascension ~ 293 ° ± 10 °, declination ~ 36 ° ± 10 °, which in turn leads to the prediction of a new anisotropic interaction of nature, also called "the new force" .

The new force acts when both of the conditions described below occur.

First condition: the modulus of the summation vector potential resulting from the sum of Ag and the vector potentials associated with all known force fields, as well as almost always collinear with Ag due to the enormous value of the latter (around 1.95 IO < 11> Gs * cm, a quantity that cannot be increased), is reduced by some sufficiently intense vector potential whose direction is sufficiently antiparallel with respect to Ag, leading to a significant value of ΔΑ∑, or to a significant variation of the summation vector A∑.

Second condition: the spatial gradient of the same quantity ΔΑ∑, that is dÀA∑ / dx, is also sufficiently high.

If the above two conditions are met, the new force, expressed as

it acts with maximum intensity along the generatrices of a cone whose axis corresponds with the Age vector whose angular opening is 90-100 °.

Note that the force fields at the origin of the two factors making up the new force can be completely different from each other: usually, the variation over time of the summation potential, ΔΑ∑, is generated by large-scale fields with very large values , such as the Earth's gravitational field, the intensity of which varies for example along a vertical path. The spatial gradient dÀA∑ / dx can emerge from force fields on a local scale, such as magnetic fields originating from local variable electric currents and having much lower absolute intensities than the former but subject to very intense spatial variations and, as such, in able to act as "amplifiers" of the large-scale fields with respect to the local intensity of the new force.

This means that by simultaneously decreasing the modulus of Ase to make the aforementioned decrease rapidly variable in space, thus giving rise at the same time to relevant values of both ΔΑ∑ and the relative gradient 3ΔΑ∑ / 3Χ, any body located in the region where the Ag modulus is decreased it will undergo the action of the new force, capable of expelling matter, and therefore mass, from the region with said weakened As modulus. By virtue of the known correspondence between mass and energy ΔΕ = Am-c <2>, the expulsion of matter and the consequent decrease in mass in the aforementioned region of physical space is transformed into heat.

One of these techniques, known, exploits the magnetic fields and the gravitational field of the Earth together.

In this regard, for example, an international patent application W02006 / 009484 has been filed and is now known, which exploits exactly this theory for the production of heat through magnetic fields and the gravitational field.

In fact, a closed circuit is used in which the change in the modulus of As is due to the gravitational field and the gradient in space of this 3ΔΑ∑ / 3Χ decrease is due to intense magnetic fields at the microscopic scale, and this generates a new force F which determines the production of heat.

The circuit is therefore formed by one or more centrifugal pumps that generate cavitation, a phenomenon consisting in the formation of microscopic bubbles of vapor within a fluid that rapidly implode developing a considerable thermal power capable of creating a plasma zone, that is of free charges. , and a closed circuit that develops in height from the pumps to close on the pumps themselves.

The rapid variation of the potential of the gravitational field, active on all the particles of the fluid moving along the vertical circuit, produces the variation of the modulus of the summation vector potential, that is the first factor constituting the new force: ΔΑΕ.

The development of a significant cavitation is necessary for the production of microscopic but intense electric currents due to the rapid movement of the plasma, and therefore of very intense local magnetic fields. Each of these magnetic fields is associated with a vector potential whose direction coincides with that of the electric current at the origin of the magnetic field, said direction pointing towards all directions of physical space as it is associated with a motion on a toroidal path due to the combined effect of longitudinal thrust and rotation induced by the vanes of the centrifugal pump.

At any instant, provided that the cavitation is sufficiently intense, there are therefore vector potentials of very intense local magnetic fields collinear to the cosmological vector potential A, and in the opposite direction, such as to determine a consistent variation along the path of the extent of the variation (decrease) of the summation potential Ag, constituting the second factor of the new force: 3ΔΑ∑ / 3Χ.

That said, this theory has never been used and above all structurally adapted and optimized in the technical field of water desalination.

According to the known art, desalination can be obtained according to different processes, which however require the use of complex and expensive technologies or large quantities of electrical or thermal energy (heat).

To the class of complex and expensive technologies belongs, by way of example, the technical note of reverse osmosis, which, at present, is the most widely used. It is made by means of separation membranes and powered directly by electricity. Frequent encrustation of membranes represents a major problem of this technique.

All the known techniques of desalination by evaporation and cooling and then condensation belong to the class of technologies that require large quantities of energy, in turn powered by electricity or directly by thermal energy derived from the combustion of gaseous, liquid or solid fuels. In these techniques, heat is needed to cause evaporation of water containing salt (eg sea water). The water, during the evaporation process, releases the salt contained in it for the simple fact that it is very heavy. The evaporated water is conducted along a cooling path inside a second container where it condenses completely purified. The energy consumption of these latest technologies is so high that the relative economy is achieved only in the case of cogeneration, therefore the use of waste heat from thermoelectric or even nuclear processes, or in the case of the use of renewable sources such as solar energy. In particular, in the case of renewable energies, they are in any case reserved for discontinuous, occasional and small-scale processes.

More innovative processes, such as those of electrodialysis, ion exchange and filtration in nano-tubes still have to prove their practical applicability.

Summary of the invention

It is therefore an object of the present invention to provide an innovative device, and relative method, for the desalination of water which at least partially solves the aforementioned technical drawbacks.

In particular, the aim of the present invention is to provide an innovative device, and relative method, which allows to cause the evaporation of the salt water and the subsequent condensation of the fresh water, through a system of simple construction and management, cheaper than systems. traditionally known, robust and energy efficient.

These and other objects are therefore achieved with the present device (1) for the desalination of water according to claim 1.

The desalination device (1) comprising: A closed primary path (10, 3 ', 3' ', 3' '', 4, 15) of circulation for a liquid to be desalted, the path (10, 3 ', 3' ', 3' '', 4, 15) being configured in such a way as to achieve a predetermined jump in height (h) for the circulating liquid.

Heating means (2, h) to raise the temperature of the liquid circulating within the closed path. In particular the heating means comprising in combination at least one centrifugal pump (2) arranged along the primary path, to generate a thrust for the liquid, and the height jump (h) in such a way that the combination between the magnetic fields, due cavitation generated by the centrifugal pump (2), preferably in the portion of the circuit (3 ') coming out of a throttle (10), and the jump in qravitational potential for the circulating liquid due to the height jump (h) of the path cause a variation of the summation vector potential A∑ and a gradient of the same aforesaid variation such as to produce a heating of the circulating liquid.

According to the invention, the device (1) further comprises a pressure valve (5) and a secondary path (6, 8) for condensation of a vapor. The secondary path is connected to the primary path through said pressure valve (5) in such a way that, in correspondence with the heating of the liquid circulating in the primary path, the pressure of the generated vapor causes the opening and consequent entry of the steam into the secondary path of condensation of the vapor obtained.

In this way, all the objectives set by the invention are achieved as this device is extremely effective (since it does not require expensive energy sources in addition to the electrical energy capable of operating the pumps, however necessary for the circulation of the water). Furthermore, the device is structurally simple and economical both in the construction phase and in the management phase, as well as being particularly robust and reliable.

The relative method therefore provides for the heating of a circulating liquid to be desalted inside a closed primary heating circuit, formed for example by a pipe that creates a certain level difference (h).

The water is pushed along the circuit through a centrifugal pump (2). During the circulation, the water gradually heats up (according to the aforementioned Byuon theory) to the point of starting to evaporate and thus penetrating into a secondary condensation circuit (6, 8) through a pressure valve (5) which connects the secondary condensing circuit with the primary heating circuit

Further advantages can be deduced from the dependent claims.

Brief description of the drawings

Further characteristics and advantages of the present device, according to the invention, will become clearer with the following description of some embodiments, given by way of non-limiting example, with reference to the attached drawings, in which: - figure 1 shows a device desalination according to a first embodiment;

- Figure 2 shows a variant of the desalting device.

- Figure 3 shows a detail of the connection at the outlet from the centrifugal pump.

Description of some preferred embodiments

Figure 1 describes a desalting device 1 according to the present invention.

The device provides a centrifugal pump 2 and a closed circulation path (10, 3 ', 3' ', 3' '', 4, 15) within which circulates a liquid to be desalted, for example sea water or brine.

The path, as shown in Figure 1, is formed by a first vertical section 3 'of height h in such a way as to create a difference in level for the circulating liquid and therefore a change in gravitational potential.

The ascending section 3 'is then connected to a descending section 3' 'through an inverted "U" shaped connection 3' ''.

The descending section 3 '' ends on a containment tank 4 for the circulating liquid (for example water to be desalted). The tank 4 is provided with a thermometer 9 to display the temperature rise (and therefore the temperature of the liquid).

A return section 15 conveys the liquid again from the tank 4 towards the pump 2.

In use, therefore, the centrifugal pump 2 pushes the liquid into the circulation along the rising portion 3 ', thus generating a predetermined cavitation 20 indicatively represented in Figure 1 through the checkerboard portion 20.

As per the preamble of the known art, the combination between the magnetic fields linked to the circulation of the plasma, due to the cavitation generated by the centrifugal pump 2, and the gravitational potential jump for the circulating liquid, due to the height jump h of the path, cause a variation of the summation vector potential A∑ and a gradient of the same aforementioned variation. These variations cause an increase in the temperature of the water and therefore a heating of the circulating liquid.

In this sense, the water that continuously circulates under the thrust action of the pump 2 undergoes a progressive increase in temperature which is displayed and measured by the thermometer 9.

Continuing in the description, and always with reference to Figure 1, at the top of the inverted U there is a pressure valve 5, or pressure gauge, whose opening and closing is determined when a predetermined threshold value of the pressure is reached.

In this sense it is evident how various types of valves can be used and whose opening and closing is controlled by specific selected pressure values.

The primary path is preferably, but not necessarily, made of PVC material which has good thermal insulation properties to favor the temperature rise.

The valve 5 is connected to a second section of pipe (6, 8) for cooling the steam which ends inside a second containment tank 7 intended to contain the liquid purified from the salt.

The secondary section is preferably, but not necessarily, made with a metal pipe which dissipates the heat much better.

In use, therefore, the water circulates along the path formed by the primary pipe (10, 3 ', 3' ', 3' '', 15) and by the tank 4 (see liquid flow arrows) arranged together with the pump in in such a way as to form the closed circuit. The pump 2 pushes the liquid in such a way as to generate the cavitation indicated in figure 20. The temperature of the water rises progressively and with it the evaporation rate, the latter also partly achieved through the same cavitation that in fact realizes a "local" evaporation.

According to the circulating liquid, a suitable valve 5 can be selected which, having reached a predetermined pressure value of the steam generated, opens giving free access to the steam inside the section 6 and 8.

However, the manometer 5 in question is preferably set, in particular in the case in which the liquid is water, in such a way as to open when a pressure value of the order of 1.7 Atm is reached. This is in fact a pressure value at which cavitation is maximized. Consequently, the action of the new force predicted by the Byuon theory, as well as the production of thermal energy, as reported in the prior art section, is maximized and with them the production of steam is therefore maximized.

Along this path (6, 8) the vapor progressively releases heat to the external environment, condensing and thus returning to the liquid state inside the container 7. In this phase, now, the liquid is completely purified from the salt which remains trapped in the circuit closed primary (10, 3 ', 3' ', 3' ', 4, 15), up to possible precipitation in tank 4 in case of interruption of the process.

Although not necessary, the circulation circuit of the vapor produced (circuit 6, 8) can be coupled to auxiliary cooling or heat exchange systems which favor the passage of state from vapor to liquid in a much faster way. Otherwise, as shown in Figure 1, the passage of heat can be entrusted with a simple heat exchange between the pipe and the external environment.

According to the invention, it is essential that the value of h, and therefore the potential jump, is at least equal to or greater than about 2.4 meters and preferably at least equal to or greater than 2.5 meters. In fact, it has been experimentally verified that this jump allows a strong variation of ΔΑΕ and therefore a considerable increase in the new force F.

An optimal value is for example the value of 2.6 meters.

Again as shown in figure 1 at the outlet from pump 2, in order to connect the aforementioned pump to the section of pipe 3 'where cavitation (and therefore heat) develops, a restricted section 10 is provided which has a diameter d of passage of the fluid restricted with respect to the diameter D of the rest of the pipe and in particular of the subsequent portion 3 '.

It is essential that, in order to optimize heat production, both D and d have values such that their ratio is within a predetermined range. This reduced section, in the correct ratio with respect to section D, as well as the dimension of D itself, amplifies the effect of cavitation and therefore of the subsequent production of heat.

In particular, by indicating with d the diameter of the restricted portion 10 and with D the diameter of the pipe in the portion 3 ', the ratio between the square of D and the square d must be between 1 and 100.

At the same time it is important that D is between 7.9 cm and 11 cm.

In fact, it has been surprisingly found that the combination of these two structural factors is able to amplify the cavitation process that optimizes heat production.

In fact, the same increase in cavitation is not trivially obtainable by selecting a pump of larger dimensions since, as will be better illustrated in the following, there is an upper limit to the capacity of the pump in relation to the volume of circulating liquid, and the choice of a higher power and possibly the size of the pump is limited only to the need to circulate a greater quantity of liquid.

Figure 3 shows the liquid fluid which, entering the rotor of pump 2 through the connection with the circuit 15, then proceeds in the first section (d) 10 with a length of about 150-200 mm and of which 100-150 mm on the outside of circuit 3 '. The diameter "d", as always indicated in figure 3, has values included in the range between 13-15 mm and therefore enters the "final" section 3 'with a diameter "D" preferably of 10 cm (100 mm).

The final section 3 '(i.e. D) can in any case have values included in the range between 7.9 cm and 11 cm so that the ratio between the aforementioned diameters (D <2> / d <2>) responds to the following relation: 1 <(D <2> / d <2>) <100.

In a possible dimensional example, D = 100 and d = 15 can be selected so that their ratio squared (100 <Λ> 2) / (15 <Λ> 2) is equal to 44 and therefore between 1 and 100.

Although, as mentioned, preferably D must be between 7.9 cm and 11 cm and, therefore, contextually d must be between 13 mm and 15 mm, however other values could be selected as long as the condition of 1 <(D <2> / d <2>) <100.

The aforementioned ratio (D <2> / d <2>) and, above all, the dimension of the diameter "D" of the "final" tube, are such as to maximize the electric currents (and therefore the magnetic fields) due to cavitation, thanks to the "quantum information channel", a direct consequence of the Byuon theory.

Continuing in the structural description of the invention, figure 2 represents a variant of the invention which is absolutely identical to the previous one except for the fact that there are two centrifugal pumps in parallel and both connected to the section 3 '. It should be noted that each of the connections of said pumps to the pipes always occurs through a throttling which amplifies the cavitation effect.

The advantage of said configuration is that of further optimizing the production of heat since said configuration, by providing a further entry of liquid fluid at high speed into the circuit, increases the generation speed of the cavitation bubbles in the above-described zone 20.

Even the use of a specific centrifugal pump is able to further optimize the heating effect obtained. In particular, it was found that the pump used should preferably be a single-stage centrifugal pump and in any case characterized by a unitary absorption of energy U (expressed in Watt / liter) which is in a relationship 0 <U <39-3X with X the number of stages of the centrifugal pump, thus forming a flow downstream of the pump that satisfies the following relationship:

Where Vo is the volume of liquid in the circuit and w is the pump capacity in cubic meters / hour.

Evidently, the above relationship therefore places an upper limit on the pump capacity, w, with respect to the volume of the circulating liquid, Vo thus limiting us in the choice of pump size. From here it is evident how inventive the choice of the aforesaid sections D and d is to maximize the cavitation effect.

Claims (1)

CLAIMS 1. A liquid desalting device (1) comprising: - A closed primary path (10, 3 ', 3' ', 3' '', 4, 15) of circulation for a liquid to be desalted, the path (10, 3 ', 3' ', 3' '', 4 , 15) being configured in such a way as to achieve a predetermined jump in height (h) for the circulating liquid; - Heating means (2, h) to raise the temperature of the liquid circulating inside the closed path; - said heating means comprising in combination at least one centrifugal pump (2) arranged along the primary path, to generate a thrust for the liquid, and the height jump (h) in such a way that the combination between the magnetic field, due to the cavitation generated by the centrifugal pump (2), and the qravitational potential jump for the circulating liquid due to the height jump (h) of the path cause a variation of the summation vector potential A∑ and a gradient of the same aforementioned variation such as to produce a heating of the circulating liquid; characterized in that the device further comprises a pressure valve (5) and a secondary path (6, 8) for condensing a vapor and connected to the primary path through said pressure valve (5) in such a way that, at the heating of the liquid circulating in the primary path, the pressure of the generated vapor causes the opening and consequent entry of the vapor into the secondary condensation path of the vapor obtained A liquid desalting device (1), according to claim 1, wherein the height (h) of the jump made by the route is at least equal to or greater than 2.4 m, preferably greater than 2.5 m, and in which, furthermore, the portion (10) leaving the centrifugal pump (2) has a throttle (10) whose diameter (d) is in relation to the diameter (D) of the subsequent portion of the portion (3 ') according to a relationship 1 <(D <2> / d <2>) <100. A device (1) for desalting a liquid, according to claim 2, in which said diameter (D) is comprised within a range of values between 7.9 cm and 11 cm and the diameter (d) of the restriction (10) is included within values between 13 mm and 15 mm. A desalting device (1), according to claim 1, wherein said primary path and said secondary path are formed by a pipe. A desalting device (1), according to claim 1, in which the secondary path ends within a collection tank (7) for the condensed steam. A desalting device (1), according to one or more preceding claims, in which the secondary path is connected with an auxiliary cooling system. A desalting device (1), according to one or more preceding claims, in which the centrifugal pump (2) is selected in such a way as to further satisfy the following condition: 0 <U <39-3X with X the number of pump stages centrifuge and with U the unitary absorption value of the pump energy expressed in Watt / liter. A desalting device (1), according to one or more preceding claims, in which the centrifugal pump (2) is a single-stage pump. A desalting device (1), according to one or more preceding claims, in which two or more centrifugal pumps (2) are provided. A desalting device (1), according to claim 1, in which the pressure valve (5) is set in such a way as to open when a pressure value of the order of 1.7 Atmospheres is reached.