MAGNETISED WATER

The invention refers to an installation and a procedure for obtaining magnetised water which can be used for curative purposes, for the treatment of some human diseases or for plants' treatment.

Information is available on installations for obtaining magnetised water, which include some permanent magnets arranged on a bearer with a cylindrical inside, through which the water, before leaving the pipe by means of a pump, crosses the magnetic field created by magnets, in order to be magnetised for plants' treatment.

The disadvantages of these installations consist in that they do not have high capacities for the magnetisation of water.

There are known proceedings for obtaining the magnetised water by pushing of a water flow with determined volume and speed in a magnetic field realized by permanent magnets.

The disadvantages of these procedures consists in the relatively low value of water magnetisation and reduced stability in time.

The issue of magnetised water that solves the invention consists in continuously preparing magnetised water , with the possibility to vary the magnetisation level.

1. According to the invention, the installation eliminates the disadvantages stated before, by using a pipe for the evacuation of the water from the first reactor chamber; it is connected to a pipe having an electric valve on the inside, being in communication with an aspiration pipe of a pump which pushes the water through a pipe having inside an electric valve into the chamber of the second reactor. To this pipe there is connected another pipe through which the recirculated water is reintroduced into the chamber, by the pipe to which the water evacuation pipe from the first reactor is connected, also being connected a pipe having some electric valves inside and to which the water evacuation pipe from the second reactor chamber is connected, from which the water is pushed with a pump through a cooler and through a filter into a reservoir.

The procedure, according with the invention, eliminates the before stated disadvantages, because the water evacuated from the first reactor chamber is filtered by the coal particles and pushed into the second reactor chamber together with the circulation water from its chamber or, depending on the water level from the second reactor, is aspirated together with the water evacuated from the second reactor chamber, after the coal particles are kept by a pump, and it is stored after cooling at a temperature of 50...6O ⁰ C and filtering.

According to the invention, the installation and the procedure present the following advantages:

- the magnetised water obtained is sterile

- relatively low energy consumption

- no discharge of noxes in the environment

- leads to obtaining a secondary product consisting of a combustible gas

- the installation has relatively small dimensions.

Two examples of accomplishment of the installation and the procedure are presented below, according to the inventions from the invention group connected to fig.l, which represents:

-fig.l, overview of an installation according to the invention

-fig.2, view of a central electrode of one reactor of the installation

-fig 3, lateral view of the reactor

According to the invention, the installation is composed by some reactors A, situated in a vertical position, having each of them a casing 1 which limits the chamber a in which some electrodes 2, 3 and 4 central and respectively on the front and back side are situated in a horizontal position. From a tight closed a basin 5, in which it is introduced through a pump 6, through a pipe 7 having mounted inside an electric valve 8, the aspired water through a pump 9, from a river or lake, water is aspired through a pipe 10 by a pump 11 and pushed through a pipe 12 having mounted inside an electric valve 13 in the chamber of the first reactor A. On each casing 1 there is fixed a pipe 14 having mounted inside an electric valve 15 connected to a cooler 16 from which water, through a pipe 17, is aspired by a pump 18 and pushed through a pipe 19, having mounted inside an electric valve 20, into pipe 12 and respectively into pipe 21 having mounted inside an electric valve 22, connected to the casing 1 of the second reactor A.

The pipe 21 is connected to a pump 23 which aspires the water through a pipe 24 through a pipe 25 having mounted inside an electric valve 26 from chamber a, from whose bottom there is connected a pipe 27 connected with a filter 28 for coal retaining, to which pipe 25 is attached.

The pipeline 25 is in connection with pipe 29 having mounted inside an electric valve 30, in which a pump 31 can push water through a pipe 32, having included an electric valve 33 mounted in basin 5.

From pipeline 30, downstream of pump 31 and upstream of the electric valve 30, there is connected a pipe 34 having mounted some electric valves 35 and 36 to which a pipe 37 is connected, having a electric valve 38 mounted. The pipeline 37 is mounted in connection with a filter 39, to retain carbon in which water from the chamber a of the second reactor A is inserted through a pipe 40 connected to casing 1. Water from pipe 34 is aspired by a pump 41 and pushed through a pipe 42 through a cooler 43 and that through a filter 44 for retaining the other impurities to a magnetised water tank 45. Each reactor A has some 46,47 and 48 level, temperature and pressure sensors.

The gas formed in the chamber a, due to electrical discharges between electrodes 2,3 and 4 into the water is discharged through pipelines 49 and 50, through some filters 51 and 52, to separate steam, from which the gas, through pipelines 53 and 54, having mounted electric valves 55 and 56 is aspired by some compressors 57 and 58, and pushed through some pipes 59 and 60, with electric valves mounted 61 and 62 and some tanks 63 and 64, the latter are in communication through pipes 65 and 66, with some electric valves 67 and 68 mounted, with some 69 and 70 electricity generators, which, by power lines 71,72, general order panels 73 and 74, secondary panels 75 and 76 for the supply of engines 77, 78 and 79, for the drive of electrodes 2,3 and 4.There are also supplied with electricity. Batteries 80 and 81 are also supplied with electricity by accumulators. Tanks 63 and 64 are connected by means of electric valves 82 and 83 having mounted electric valves 84 and 85, with a collector 86 having mounted an electric valve 87, an electric current generator 88, provided to consumers.

The electrode 2 is fixed to a shaft 89, preferably made from stainless steel supplied with electricity through brushes 90. The shaft 89 passes through casing by means of a sealing gland 91, and ,outside casing 1, a snail wheel 92 is attached to shaft 89, engaging with a worm 93, rotated by an electric motor 77 fixed by means of screws 94 on a mobile plate 95. On casing 1 there is attached a vertical plate 96, to which two guides 97 and 98 are attached, along which the plate 95 may be moved by means of guidance ball joints 99. The spindle 89 is provided with a nut 100, which in turn engages with a coarse thread screw 101, involved in rotational motion by an electric motor 102, supported by a horizontal plate 103 fixed to plate 96. The nut 100 is bottom guided by a ball coupling 104 mounted on two bars 105 attached at the sides by plate 103.

Electrodes 3 and 4 are mounted on each one of the axes 106 and 107 which are now connected to a source of electricity and which cross casing 1 through glands 108 and 109, and which may be moved horizontally with one of the nuts 110 and 111, which engages with one of coarse thread screw 112 and 113, in turn engaged in rotational motion by one of the 78 and 79 electric motors. The latter are supported by one of the vertical plates 114 and 115, fixed to the casing 1. The boards 114 and 115 are provided on the sides with some pairs of horizontal bars 116 and 117, which are in lower contact with nuts 110 and 111.

According to the invention, the process applied in the installation includes the introduction of water from the river or lake in chamber a of the first reactor A, ^% to achieve a predetermined level, confirmed by the sensor 46 after the electrodes 2, 3 and 4 are supplied with electricity at a voltage of 50V and an intensity of 1500 so that electrical discharges occur between them, and thus a gas composed of hydrogen and oxygen appears and water heats up to a temperature of 100 ... 130 ° C. The resulting gas is discharged from the a chambers, separately from the steam and compressed in order to be stored for the supply of electricity generators 69 and 70 for internal consumption, respectively of the electricity generator 88 for consumers. The water in the a chambers is permanently circulated by one cooler 16, which cools the water to a temperature of 50 to 6O ⁰ C, after which it is introduced through pipe 12 into the a chamber of the first reactor A, and respectively through a pipe 21 connected to a chamber of the second reactor A. In pipeline 21, the water suctioned from a pipe 24 is forced by pump 23 and pipe 24 is connected to pipe 25, through which water is discharged from the a chamber of the first reactor after it was passed through the carbon retaining filter 28. Also, pipeline 25 is connected to pipeline 29, which communicates with pipe 24 from which water can be pushed by the pump 31 into basin 5. Water from pipe 29 is sucked by the pump 41, and ,after it is cooled to a temperature of 50 ... 60 ° C, and filtered, it is pushed into tank 45. At the same time with water from pipe 34, the water evacuated from chamber a of the second reactor A is sucked through the pipe 40, after coal particles were retained from it.