ITBO20130584A1 - ELECTROMAGNETIC INDUCTOR EQUIPMENT AT FREQUENCIES FOR WATER TREATMENT WITH THREE INDUCTION COILS - Google Patents

Description

DESCRIPTION

of the patent for Industrial Invention entitled:

"ELECTROMAGNETIC FREQUENCY INDUCTOR EQUIPMENT FOR WATER TREATMENT WITH THREE INDUCTION COILS".

The present invention relates to the construction and management technique for inductor tube, protected by shielding, consisting of three coils for water treatment.

This water treatment technique is not present on the market. Researchers such as Masaru Emoto, Jacques Benveniste, Massimo Citro (discoverer of the TFF frequency pharmacological transfer) have demonstrated the memory capacity of water and the transmission of stored frequencies. While Calf Rife 1940, was the discoverer of the destructive or inhibitory action of frequencies on pathogens in general and without limits.

The construction and powering criteria of the three induction coils allow the application of the aforementioned techniques for industrial and agricultural uses.

The water is able to memorize and maintain the vibration of electromagnetically induced frequencies at 100% for 48 hours. The intensity of vibration is directly proportional to the intensity of the induced magnetic field.

This technique used in agriculture, through irrigation over the foliage, allows the transmission of frequencies corresponding to fertilizers to the plants, with a stimulating effect for the vital systems of the foliar apparatus, of the root system, increasing production over 20% in a biological way.

By inducing the frequency of Sulfur or Copper Sulphate, etc. to the irrigation water, it is possible to carry out treatments with 100% effectiveness without leaving any chemical residue on the products, plants and soils.

The present invention is also intended to treat water to be purified, by transmitting the three frequencies to the water it is possible to break up polluting molecules such as: 90% nitrates; 100% fluorides; 100% arsenic; 100% pesticides; 100% insecticides; 100% fungicides; herbicides 80%.

For each pollutant, an inductor with three coils is required, as to generate the disrupting high frequencies, the overlap of the three waves that are perceived by the polluting molecules immersed in the water as a single frequency up to 800 times greater (MHz) (and beyond) is required. of induced frequencies. Therefore, for more pollutants, more inductors in series will be inserted in the purification circuit.

DESCRIPTION

The project of fig. 1 consists of an inductor tube 9 superimposed by three induction coils A-B-C, placed inside a shielding box 10, a flow limiting valve 15, a flow transducer 14, a pressure transducer 13, the three coils A-B-C are powered by a module 11 containing three programmable square wave frequency generators 18 (PFG) with the precision of 1 Hz, through the connection cables 16 and controlled by the control module 19, a switch 17 activates the coil D-E (fig. 3) to operate from 50 to 130 KHz or the two coils in series D-F for frequencies from 5 to 50 KHz.

The tube defined INDUCTOR 9 is made of insulating material and transparent to magnetic fields such as PVC or Polyethylene, it must have an internal surface, equal to or greater than three times the internal surface of the supply tube 1. The material used, suitable for the application, will have a pressure limit, this determines the thickness of the inductor tube 9 and the external diameter. This external diameter of the inductor tube 20 fig. 2 (defined D1) is used as a reference for subsequent sizing. The length 3 of the coils (A-B-C) corresponds to 1, 5 x D1, the spaces 4 between the coils correspond to 1 x D1. The shielding box is made of 15/10 thick steel, the distance from the inductor tube 21 fig. 2 is 1.5 x D1, also the side closures fig. 2 of the shielding box are positioned at a distance of 5 from the coils (A-C) of 1, 5 x D1.

From these data we obtain the length of the inductor tube 9 is determined by the sum of the values in references 3-4-5 of fig. 1, adding to the total 10 cm of margin outside the shield to install the reductions from the diameter of the inductor tube to the diameter of the inlet hose 1.

The length 6 of the shielding box 10 is determined with the sum of the values in references 3-4-5 of fig. 1, the width of the sides 7-8 is determined by the distance 21 fig. 2, of 1, 5 x D1 x 2, plus the diameter of the tube 20. This measure 6 also corresponds to the length of the inductor tube immersed in the magnetic field, useful for determining the volume of water in transit, essential for calculating the flow rate in liters per hour, as a function of the exposure time to the magnetic field which must not be less than four. seconds.

The calculation of the flow rate is given by the internal surface of the inductor tube 9 for its length 6 and corresponds to the volume of the inductor tube. Then we take the 3600 seconds of an hour and divide them by the seconds provided for by a minimum of four, and we multiply the result by the volume, we will have the liters per hour of flow rate of our tube. The control module 19 processes the flow rate detected by the flow transducer 14 and, based on the volume of the tube 9, displays the resulting induction time on the display, the latter expected in the range from 4 to 15 ". This value is adjusted, according to the treatment requirements, by means of the valve 15. The pressure transducer 13 detects the operating pressure and if it exceeds the limits of the inductor tube, the control module 19 activates an alarm state. Alarm activated also for changes in the flow rate compared to the expected value.

Coils 3 (A-B-C) are the same in construction fig.3. These consist of a winding with central socket E, made with wire with a section (defined as S) suitable for the maximum expected current, and of two superimposed layers of length 1, 5 x D1 ref. 3 fig 1. To reduce the capacitive effect between the coils, these are spaced apart by the space corresponding to the diameter of the wire used. A 2mm thickness of insulating material for windings must be inserted between the first and second layer.

The number of turns of the single coil (A-B-C) 22 or 23 fig. 3 is determined by the length (defined L1) of the coil 3 divided by S and the result divided by two (L1 / S) / 2 gives us the number of turns for each layer .

To determine the section of the wire, which is proportional to the diameter of the inductor tube, it is necessary to start from the minimum intensity of the magnetic field, necessary to inform the water and is approximately 90 amperspire

The coils are designed for frequencies from 5 to 130 kHz: between connections D-F 22 and 23 one operates on frequencies from 5 to 50 kHz, with currents up to 5 A indicative; while to operate from 50 to 130 kHz it is necessary to connect the coil D-E 22, for currents up to 13 A, indicative and non-limiting values. To power the coils at the various predetermined frequencies and minimum necessary currents, the direct current power supply voltage of the PFGs must be adjusted in the range from 150 to 1000Vdc with steps of 50V. Switching between D-F and D-E takes place automatically by means of the control module 19 which intervenes on the switch 17.

PRACTICAL EXAMPLE OF SIZING

Having the supply tube 1 with an internal diameter of 100mm, we will have a surface of 78.5 cm <2>, to determine the minimum surface of the inductor tube, we will have 78.5x3 = 235.5 cm <2> equal to the internal diameter of 173 , 2 mm. Using a polyethylene pipe for a pressure of 16 bar, we will have a 225 mm pipe with external diameter and 180 mm internal diameter, therefore the external diameter 225 mm is our reference measure D1 (fig. 2 -21). Therefore we will have the spaces between the coils 4 = 1xD1 = 225 mm, the coils 3 = 1, 5 x D1 = 1, 5 x 225 = 337.5 mm, as the distance of the shield 5 = 1, 5 x D1 = 1, 5 x 225 = 337.5 mm. The length of the inductor tube 9 will therefore be the sum of the spaces 4, the coils 3 and the spaces 5; 225x2 337.5x5 = 2137.5 mm plus 100 mm for the connection of reductions from 225 to 100 mm, total 2237.5 mm.

The shielding box 10 will therefore be 6 = 2137.5 mm long with sides 7 = 8 squares determined as follows: insulation distance 21 from pipe 9 equal to 1, 5 x D1 = 337.5 mm for two plus the diameter D1 20 of 225 = 900 mm.

Conclusion the shielding box 10 will have the dimensions of H 900 x L 2,137.5 x P 900 mm with a hole of 235 mm centered on the sides, steel sheet 15/10.

Sizing of the coils (A-B-C), considering the use of enameled wire for windings class F for a maximum temperature of 200 ° C with a section of 1.9 mm for a maximum current of 11, 34 A RMS, considering that the coils are installed directly above to the tube in which the water flows internally, there will be a direct cooling which allows to reach 15 A of current in continuous service. The number of turns of the single layer is determined by the length of the coils 3 equal to 1, 5 x D1 = 1, 5 x 225 = 337.5 mm, considering the section of 1, 9 mm we will have a total of 337.5 / 1 , 9 = 117.6, since the coils are spaced apart by the same section of the wire 1, 9 mm, the resulting coils for each layer will be 117.6 / 2 = 59 coils (rounded value) corresponding to the winding D-E. Subsequently, an insulating thickness of dielectric material of 2mm will be superimposed and on top of this another 59 spaced coils will be wound to form the E-F coil.

Calculation of the flow rate: considering that the water passing through the pipe must remain at least four seconds, we will have an internal diameter of 180 mm, for a surface of 25,434 mm <2> For the length of the inductor tube 9 of 2,137.5 mm, we will have a volume of 54.365 cm <3> converted into 54.365 liters every 4 ”seconds for a flow rate of 48.928.5 liters per hour.

Claims (5)

CLAIMS 1. Frequency electromagnetic inductor equipment for water treatment, with three induction coils wound on a plastic material tube (such as polyethylene), through which water passes at a speed such as to allow exposure to the magnetic field for programmable times from 4 to 15 seconds; the tube with the three coils is contained inside a shielding box. 2. According to claim 1, the apparatus consists of an inductor tube superimposed on three induction coils, the length of the coils equal to 1, 5 the external diameter of the inductor tube, the distance between the coils equal to the diameter of the inductor tube, the 15/10 sheet steel shielding box must be equidistant from the coils by at least 1.5 the outside diameter of the inductor tube. 3. According to claim 1: the coils are the same in construction. These consist of a winding with central grip, made with wire with a section suitable for the maximum expected current and two superimposed layers with a length of 1.5 times the external diameter of the inductor tube. To reduce the capacitive effect between the coils, these are spaced apart by the space corresponding to the diameter of the wire used and a 2mm thickness of insulating material for windings must be inserted between the first and second layer. The number of turns of the single coil is determined by the length of the coil divided by the section of the conductor used and the result divided by two, gives us the number of turns for each layer. 4. According to claim 2 the same technique can be used with inductor tubes of different diameters, the limit is imposed by the available electronic technology. 5. Technique: the three coils are powered by a frequency generator module capable of delivering predetermined frequencies in the range from 5 to 130 kHz with the precision of 1 Hz square wave, current up to 13 A and variable supply voltages to the power generators. frequencies, from 150 to 1000Vdc with steps of 50V, managed by a control module. These are indicative and non-limiting values.