IT201600092448A1 - Method and device for the implementation of said method for the realization of anti-scale, antibacterial and floculating treatments - Google Patents

Description

METHOD AND DEVICE FOR THE IMPLEMENTATION OF THIS METHOD FOR THE IMPLEMENTATION OF ANTI-SCALE, ANTIBACTERIAL AND FLOCULATING TREATMENTS

The present invention refers to a method, and to a device for the implementation of said method, for the realization of anti-limescale, antibacterial and flocculating treatments. These treatments, operated on hydraulic circuits, are based on the use of electromagnetic waves.

Electromagnetic devices for water treatment are known, with an anti-limescale, antibacterial and flocculating function. In practice, these devices induce an electromagnetic wave in the water that interacts with the electrically charged substances (for example ions) or dipolar substances present in the water and with the water itself, triggering phenomena that prevent the deposit of limestone deposits on the walls. internal tubes, or producing antibacterial and flocculating effects.

To achieve this result, said known devices generally consist of a monoblock containing an electronics capable of powering a toroid which, like the core of a transformer, adopts a water pipe as a secondary.

The effect is to induce an electromagnetic wave in the water, accompanied by an electric current in the tube itself.

When the device is applied to a single pipe, it works correctly, but if said pipe is part of a more complex hydraulic circuit and the ends of said pipe are somehow in electrical contact with each other, and therefore a low or low loop is formed. very low impedance, the current induced in the circuit is exhausted in the loop and does not act outside the loop itself. It should be noted that as soon as the hydraulic circuit has a minimum of complexity, it is not easy to recognize the existence of loops, as the closure of any loops can also take place in places of the system far from the point of installation of the device and substantially inaccessible. .

The devices of the prior art are not able to work satisfactorily when the signal is entered inside a very low impedance loop (similar to a short circuit). In this case, the primary of the transformer is not able to provide adequate power, because the electrical current on the primary should assume values so high as to be incompatible with the integrity of the electronics supplying the primary itself. Then the electronic apparatus is put into protection by automatically reducing the power, the more the lower the impedance of the loop, until it becomes completely ineffective for short circuit values.

Often these devices are also equipped with notifications that are not suitable for signaling the presence of loops, so it may happen that the installer does not even realize that he has mounted the device in an ineffective way. In practice, it happens that the device is not very effective in the loop and is totally ineffective on the rest of the system.

The present invention solves the problem posed by proposing a method and a device, respectively in accordance with claims 1 and 5, for obtaining an anti-limescale, antibacterial and flocculating effect in hydraulic circuits in which at least one loop is present.

The method is of the type that uses electromagnetic waves induced in said hydraulic circuits and is characterized by the fact that said electromagnetic waves are isochronous, as described below, and are induced in two distinct points of said at least one loop, said condition being suitable for ensuring a propagation of the signal outside said at least one loop.

The device is of the type which provides an electronic apparatus capable of generating alternating electrical signals which are sent to inductors to be applied to the pipes of the hydraulic circuit to be treated, said inductors being able to transmit said alternating electrical signals to said hydraulic circuits by electromagnetic induction, and is characterized in that said electronic apparatus is able to simultaneously produce a first signal, to be sent to said first inductor, and a second signal, to be sent to said second inductor, said signals being correlatable in amplitude, frequency and phase, depending on the hydraulic circuit to be treated and the desired result.

The use of a device according to the invention therefore allows to effectively treat hydraulic circuits including loops.

The invention will now be described, for illustrative and non-limiting purposes, according to a preferred embodiment and with reference to the attached figures, in which: • Figure 1 shows the system according to the invention, applied to a pair of pipes;

• figures 2 (a, b) show construction details of the inductors;

• figures 3 (a, b) show possible signals emitted by the system according to the invention;

• Figures 4 to 8 show different possible installations, depending on the characteristics of the hydraulic circuit and / or the results to be achieved.

With reference to Fig. 1, with (1) is indicated an electromagnetically operated anti-limescale, antibacterial and flocculating device, according to the invention.

Said device (1) comprises an electronic apparatus (2), powered through a wiring (3) and connected, by means of coaxial power cables (4a, 4b), to a first inductor (5a) and to a second inductor (5b) . Said inductors (5a, 5b) are mounted, for example by clamps (6), on respective pipes (7a, 7b) of the hydraulic system to be treated.

The transmission of the signal emitted by the electronic apparatus (2) to the water contained in the hydraulic circuit (7a, 7b) occurs by electromagnetic induction, in fact the two inductors (5a, 5b) are equipped with toroidal magnetic cores (8a, 8b) which wind around said tubes (7a, 7b). In practice, the toroidal magnetic cores (8a, 8b) are like transformer cores, in which the primary is constituted by the two inductors (5a, 5b) and the secondary by the tubes (7a, 7b), with the water contained inside . This means that a signal that the electronic apparatus (2) sends to said inductors (5a, 5b) corresponds to a signal induced in the pipe, according to the well-known laws of electromagnetic induction.

According to a preferred embodiment, shown in Figs. 2 (a, b), said toroidal cores (8a, 8b) are obtained by joining together elements (9a, 9b) with high magnetic permeability, so as to form a ring that embraces the pipe. Said elements can be straight, referenced with (9a) in Fig. 2a, or have a Z shape, referenced with (9b) in Fig. 2b. In the first case, straight elements (9a), to compose a toroid it is necessary to use an even number of said elements (9a), while in the second case, Z elements (9b), this limitation no longer exists and it can be realized a toroid with both an even number and an odd number of said Z elements (9b).

Fig.3a shows a signal (10), emitted by the electronic apparatus (2) and detectable by an oscilloscope, which is transmitted, through the coaxial power cables (4a, 4b) to the two inductors (5a, 5b) . The effect is to induce an electric field E⃗ and a magnetic induction field B⃗ in the pipe, which are inverted every half-period.

The electronic apparatus (2) according to the invention is able to simultaneously produce a first signal (10a), to be sent to said first inductor (5a), and a second signal (10b), to be sent to said second inductor (5b) .

Fig. 3b shows any pair of signals (10a, 10b), that is, different in frequency, amplitude and phase. The electronic apparatus (2) is in particular able to generate signals (10a, 10b) that can be correlated in amplitude, frequency and phase, depending on the hydraulic circuit to be treated and the result to be obtained, as will be better specified below.

In Figs. from 4 to 8 various possible ways of insertion in the hydraulic circuit of the appliance (1) according to the invention are shown, said insertions being aimed at obtaining particular objectives.

In Figs. 4 and 5 shows an installation in which both inductors (5a, 5b), connected to a single electronic device (2), are installed on the same tube (7). By electromagnetic induction each toroid (8a, 8b) generates an electromagnetic wave (10a, 10b) (with a frequency comprised for example between 50 and 500 kHz, preferably between 100 and 250 kHz) inside said pipe (7) to which it is applied. The peack to peack value of the voltage induced in the secondary can be measured in Volts with an oscilloscope and is proportional to the diameter of the tube (7).

The straight arrows indicate the direction and direction of propagation of the electromagnetic waves of which E⃗a and E⃗b are the electrical component (which is the component of the wave effective for our purposes).

The circular arrows indicate in a conventional way whether the waves emitted by the two inductors (5a, 5b) have the same phase or not. Precisely they have the same phase when the ends of the arrows have the same orientation with respect to the straight arrow.

When one or the other of the waves (10a, 10b) emitted have phases that differ randomly, the orientation of each of the circular arrows is different from the straight ones.

In Fig. 4 the two inductors (5a, 5b) are installed in an aligned way, that is, so as to induce two electromagnetic waves (10a, 10b) equiverse and in phase (isochronous), as shown by the two circular arrows.

Since the amplitudes add up algebraically, the resulting signal, which will travel through the hydraulic circuit, will have a value approximately equal to the sum of the two signals (10a, 10b).

With this configuration, the anti-limescale effect is particularly enhanced (for example in pipes and heat exchangers). In this case the power of the electronic apparatus (2) can be calibrated to obtain a voltage between two points A and B and between two points C and A of the pipe (7) between 10 V and 500 V (preferably between 50 and 150 V).

Said points A and B and C and A are respectively positioned upstream and downstream of the respective toroid (8a, 8b) (with reference to the direction of the vectors E⃗a and E⃗b).

For example, with VAB equal to 100 V and VCA equal to 95 V, there will be a voltage VCB = VAB VCA = ~ 195 V.

In Fig. 5 the two inductors (5a, 5b) are installed without correlation. This configuration also implies the sum, instant by instant, of the amplitudes of each wave (10a, 10b) emitted by each inductor (5a, 5b).

Since the phase of each of the two waves (10a, 10b) is independent of each other, the resulting wave within the hydraulic circuit has a randomly variable amplitude. This installation is particularly suitable for enhancing the flocculating effect (particularly effective in filtering water in swimming pools).

In Figs. 6, 7 and 8 show typical installations of the device (1) according to the invention, that is, in systems that can be classified as "hydraulic networks", in which there are configurations with links and nodes, often referred to by the generic term of "loop". This installation is based on the properties of electrical networks (for which the two laws of Kirchhoff are valid) and the method according to the invention is able to avoid the overvoltages of short-circuits, which are fatal for the operation of the electronic emitter apparatus. (2).

Fig. 6 shows a first installation of the device (1) according to the invention on a hydraulic network. Said first installation involves the positioning of the two inductors (5a, 5b), in phase and opposite each other, on the same branch of a loop. This first installation is optimal in naval systems and swimming pools, especially due to the excellent anti-catheter effect.

According to said installation, the signal propagates outside the loop. Pipes behave similarly to waveguides.

For example, with reference to Fig. 6, with VAB equal to 100 V and VCA equal to 95 V, there will be a voltage VAD = 100 V and VEA = 95 V.

Fig. 7 shows a second installation of the device (1) according to the invention on a hydraulic network. Said second installation provides for the positioning of the two inductors (5a, 5b), in phase and aligned, on two opposite branches of a loop. This second installation is optimal for anti-limescale purposes.

According to said second installation, the signal also propagates outside the loop. Also in this case the pipes behave in a similar way to waveguides.

For example, with reference to Fig. 7, with VAB equal to 100 V and VAC equal to 95 V, there will be a voltage VAD = 95 V.

Fig. 8 shows a third installation of the device (1) according to the invention on a hydraulic network. Said third installation provides for the positioning of the two inductors (5a, 5b), in phase and opposite each other, on two branches of a loop. This third installation is optimal for obtaining the flocculation of the impurities contained in the water flow.

According to said third installation, the signal also propagates outside the loop. Also in this case the pipes behave in a similar way to waveguides.

For example, with reference to Fig. 8, with VAC equal to 100 V and VDB equal to 95 V, there will be a voltage VAB = 100 V and VCD = 95 V.

The invention has been described for illustrative purposes according to a preferred embodiment and a variant. The skilled technician in the field will be able to find numerous other embodiments, all falling within the scope of protection of the attached claims.

Claims (8)

CLAIMS 1. Method for obtaining an anti-scale, antibacterial and flocculating effect in hydraulic circuits in which at least one loop is present, said method being of the type that uses electromagnetic waves induced in said hydraulic circuits, characterized in that said electromagnetic waves (10a, 10b) they are isochronous and are induced in two points of said at least one loop, said condition being suitable for ensuring a propagation of the signal outside said at least one loop. 2. Method according to claim 1, characterized in that said electromagnetic waves are in phase and opposite and applied on the same branch of said at least one loop. 3. Method according to claim 1, characterized in that said electromagnetic waves are in phase and aligned and applied on two opposite branches of said at least one loop. 4. Method according to claim 1, characterized in that said electromagnetic waves are in phase and opposite and applied on two opposite branches of said at least one loop. 5. Electromagnetic operating device to obtain an anti-scale, antibacterial and flocculating effect in hydraulic circuits, of the type that provides for an electronic device (2), capable of generating alternating electrical signals (10a, 10b), called alternating electrical signals (10a, 10b ) being sent to inductors (5a, 5b), to be applied to pipes (7, 7a, 7b) of said hydraulic circuit and able to transmit by electromagnetic induction said alternating electrical signals (10a, 10b) to said hydraulic circuits, characterized by the fact that said electronic apparatus (2) is able to simultaneously produce a first signal (10a), to be sent to said first inductor (5a), and a second signal (10b), to be sent to said second inductor (5b), said signals ( 10a, 10b) being correlated in amplitude, frequency and phase, according to the hydraulic circuit to be treated and the result to be obtained. 6. Electromagnetic operating device, according to claim 5, characterized by the fact that said inductors (5a, 5b) comprise toroidal cores (8a, 8b), obtained by joining together elements (9a, 9b) with high magnetic permeability, so to form a chain that embraces the pipe (7, 7a, 7b) to which said inductors (5a, 5b) are applied. 7. Electromagnetic operation device, according to claim 6, characterized in that said elements (9a) with high magnetic permeability are rectilinear. 8. Electromagnetic operating device, according to claim 6, characterized in that said elements (9b) with high magnetic permeability have a Z shape, so as to create a toroid (8b) with both an even number and a number odd of said Z elements (9b).