NL1039530C2 - A DEVICE FOR REALIZING CHEMICAL COMPOUNDS THROUGH IONIZATION FOR LIQUID AND GASES. - Google Patents

Description

i

Title: a device for creating chemical compounds through ionization for liquid substances and for gases

The invention relates to the energy supply. It concerns a device 5 with which, inter alia, benzene can be made. This can simply be done by mixing water and carbon in the device, after which benzene can be obtained through a chemical reaction in the device.

Application will be found in, among other things, cars and ships, but also in home use.

This can be confirmed in a car that supplies power to the battery via hub dynamos, in this case the device is connected to the car's battery. The battery provides the device with a stable power supply.

15

For the sake of clarity, the description of the components always refers to water, which can be replaced by both other liquids and gases.

2 How the device works 20

There is a part in the device that consists of a chip structure. This chip structure is flowed through with electricity.

At the part that transmits power to the chip structure, each time with a +/- coupling 25, this chip structure is connected to distilled water, at the bottom of the chip structure there is a reservoir into which water can be added.

Upon flow of the chip structure, it supplies ions to the water, which bind with atoms, thereby charging them with atoms having structures formed by the structure of the chip structure.

Each chip structure is a circuit that can hold power on its own and each results in a different flow of electricity. The ions supplied to the water are all different in structure, but they fit into each other, which means that they blend into the reservoir and form a larger structure, a molecular shape.

The number of reservoirs determines how many bonds the formed molecules will have. For this device, a standard choice is made of 6 reservoirs at the entrance that must provide molecules with six compounds.

40

Six compounds are needed to form a hexagonal structure at the bottom of the composition. A hexagonal structure promotes the formation of gas bubbles.

The chip structures that have the composition have triangular metal 45 triangles that are placed to provide plus-pole currents with a counter force, creating a kind of through-flow, a kind of minus pole.

1039530 2

The triangles always form a triangle with a total angle of 171 degrees, compared to a total angle of 342 degrees. This means that a round shape is measured with a total of 342 degrees, a different scale than normal is calculated.

5 The triangle shapes can optionally be replaced with thrystors and diodes. Two different diodes are used for the minipole values. This is to convert alternating current to direct current. It is a single-phase rectification. Two thyristors with different holding current are used for the plus-pole values.

The chip structures are set up in such a way that it appears that water is moving into the chip structures at the top. A part has been left open where water can move. The chip structure is made watertight.

The choice is made to provide the assembly with six times parts according to number 4, whereby it is realized that hexagonal structures are realized at the bottom. A better flow is achieved.

The chip structures have a resistor. The resistors are connected to the fuse. The fuse melts at a certain temperature, usually after a short circuit caused by a resistor burning out.

The current is according to a closed circuit.

3 The parts 25 1 ionizing element, characterized in that it relates to the outer wall of the composition. This is made of material that impedes the flow of electricity, so that it is realized that the outer wall does not present a danger of electrical discharge or over voltage. The component is preferably made of PVC.

The hull consists of two parts, the top has a pivot point and a handle with which the top can be opened.

The hull has two separate parts, one intended for the chip structures and the bottom intended for the reservoirs for the liquids and gases.

In total, six entire chip structures with the characteristic of part 4 are placed side by side in the width, each chip structure having a separate reservoir. The 40 reservoirs are connected to each other at the bottom via a pipe connection, which causes the water to flow to the side in part 5, after which the water flows into the reservoir according to part 6.

The water consists of particles that come together in the reservoir in Combination with part 6 45, here another molecule is formed. There is, however, a filter between the reservoirs of the parts according to numbers 5 and 6.

3

The outside wall is provided with screw-in cavities on the inside for fixing the chip structures. These cover the top, after which no water can flow into the top of the device. A part is created where there is air, needed to dissipate the heat.

5

At the top there are hexagonally shaped holes that serve as ventilation. A tube is placed on this, which allows the air to be transported to the outlet. This air can contain toxic vapor.

The component has protrusions on the top for fixing the chip structures on the top. There are screw cavities for the reservoirs on the inside.

The composition has a ratio of 42.58 vertically and 107.56 horizontally.

2. A ionizing element, characterized in that on the hull, at the top, adjacent to the maximum position of the water, there is a sensor which indicates whether sufficient water is present in the reservoir. This is important for a good transfer of charged particles.

20

The composition can be linked via the sensor to a system that replenishes water if a certain limit is exceeded.

A manometer (or a barometer) is connected to this sensor.

3. A ionizing element, characterized in that a controller is attached to the outside of the hull, which controller records the data from the sensors in order to be able to pass them on to a third device.

The power cables of the sensors are routed on the outside and connected to the controller. This also applies to the meters.

The controller controls input connection points Before the Séhsóréh éh Output connection points for connection to a third device.

35

The controller is supplied with external power via a plug-in circuit.

The chip structures are also connected via the controller via a plug - in and output.

The cables are hidden in the hull, the power cables are pulled between the 40 output of the controller and the input of the chip structures.

The controller has a fuse that protects the device against overvoltage. This has a resistance that heats and melts at a certain temperature, as a result of which the composition no longer works.

If the fuse blows, no power is supplied to the chip structures.

45 4 4 Ionization element, characterized in that it concerns chip structures with a separate reservoir. Six of this type of chip structures with separate reservoir are placed in the width in part 1, the chip structures always placed on top. They are confirmed in such a way that it does not allow water to pass through at the top. Every time a transition from + to -, current, the electric wire of the chip structures is left open, creating an opening to the water. This makes it seem as if water is moving in the chip structures.

The negative pole is realized by working with metal triangular shapes, which conduct current. These ensure a certain flow which provides a counterforce.

Ionizing element, characterized in that it is a chip structure, which causes the atoms to flow to each other, because it binds the atoms via square-shaped electrons or ions.

15

The process resembles bonds that make amino acids through which they flow. The atoms orbit around each other and become connected to each other.

There are two variants, both have separate reservoirs, they have the same purpose but the variant allows the atoms to bind, a kind of bridge between a cross shape and a square shape. A bridge between parts 4 and 5.

The order is, first the variant, then the chip structure that causes a spin movement of atoms.

Ionizing element, characterized in that it concerns a chip structure, which causes the atoms to connect to each other, by flowing through them with hexagonally shaped electrons or ions. Here, the atoms that reach the bottom form a hexagonal structure that can more easily bind other atoms, thereby forming a molecule.

Unlike the chip structures of parts 4 and 5, the chip structure of part 6 is located inside the assembly immediately behind the filter on the bottom.

35

Many gas bubbles are formed in this section due to the formation of hexagonals.

7. A ionizing element, characterized in that these relate to sensors which are mounted on the underside and adjacent to the part 40 according to number 6. These serve to measure how many bonds have been created. A manometer (or barometer) can be placed on the sensors via the controller.

The sensors can replace her wish, her Sórt. Dèzè 45 are screwed to the outer wall of the composition.

5 The sensors must provide information to one external control device on the percentage of hangings that have been established in relation to the water.

This is done via the controller.

5

The sensors have a rear that comes into contact with the liquid or gas present on the inside.

8 ionization element, characterized; 10 that this is a filter that is placed between the hexagonal and square chip structure, an S-shape is formed, water flows in an S-shape to the underside where the hexagonal chip structure is located, which supplies the water with the last force so that atomic structures after which the water has the opportunity to bind six atoms of the same kind.

15

The filter is needed to separate the elements before reaching the final phase, separation occurs in such a way that various other connections are created that then easily establish a new connection.

The filter has a metal wire connection.

The filter is in a ratio of 42.58 vertical and 107.56 horizontal.

The filter has an ocelli - shaped outlet.

25

The splitting of gases is done via the cable connection in the semi-finished product. The tightly laid cables absorb vibrations and pass on charged ions to the substances that move in the semi-finished product. Partly because the inside of the semi-finished product is streamlined, substances will easily be absorbed by the entrance and then leave the exit.

From the differential that is formed on the inside, the gases are moved with a different charge as on entry. Up to the exit, the atomic compounds are separated from each other by charging them with positive and negative ions, at the exit again a differential is created whereby the atoms touch each other and form new substances.

9. Ionizing element, characterized in that these are T-shaped tubes, which transport the water from the water reservoirs 40 and which are attached to the tubes laterally. Water is conducted from the reservoirs to the bottom of the assembly via the water reservoir of part 6.

For a variant, it applies that these tubes concern the transport of gases.

45 10 Ionization element, characterized.

6 that these tubes are connected to the T - shaped tubes. These are made of plastic and conduct water from the front reservoirs downwards. This is the S-shaped connection that is made with the filter.

Lonization element, characterized in that part 1 is provided with two inputs. One entry is for the supply of water, the other for the supply of other components, examples of carbon for the recovery of benzene and nitrogen for the realization of H and N compounds of atoms. With six pieces of reservoirs and chip structures according to number 4, benzene 10 can be formed.

The entrance is adjacent to the pipes at the bottom. It is not necessary that the components enter the reservoirs of the component according to number 4.

The entrance has a screw cavity on the hull to which the tubes that form the entrance can be screwed.

12. Ionizing element, characterized in that part 1 is provided with an outlet at the bottom of the part, which means that the outlet of the assembly is at the bottom.

The hull has two screw cavities on the underside, on one of which is attached the tube that serves as an outlet.

25 The outlet works with an air pressure valve that allows flow through at a certain pressure, which makes it possible for liquid to be withdrawn from the composition remotely.

Optionally, the air pressure valve is omitted and a manually opening valve is placed, for a composition that does not have to be operated remotely.

A ionizing element, characterized in that it is a pressure filter which is coupled to the reservoir of part 6.

The pressure filter is set to open at a certain pressure and to allow liquid or gases to pass through. This is an emergency measure and a solution to prevent dangerous pressure formation.

The reservoir of part 6 has a screw cavity to which the pressure filter can be screwed and then it is inserted through the body.

14. Ionizing element, characterized in that these are pressure gauges (or barometers) that can optionally be attached to the body of the assembly. It is possible to choose to connect the pressure gauges (or 45 barometers) to a third system that can measure values remotely via the controller.

7

The pressure gauge (or barometer) is always connected to the controller (3), which receives data from the sensors and transmits this data.

A maximum of 2 manometers (or barometers) are placed, for a sensor according to part 2 and according to part 7.

A composition that works with air streams. A composition can be manufactured in which air is blown. The effect will be that particles in the air will deform and on the underside other molecular forms will arise. These become visible as air bubbles, these are formed in part according to number 6.

This composition requires no water and works entirely with air flows. However, the system remains the same for the rest, so in principle the composition also works with air flows.

Nitrogen compounds are realized, six compounds of nitrogen that can mix with oxygen, whereby, among other things, the gas produces NO. However, because six bonds are formed, a connection will be created with 6 N (nitrogen) bonds and 6 O (oxygen).

Because these bonds arise in a hexagonal, they will form air bubbles. It also applies to the water that air bubbles will form.

25

If desired, other gases can be added to air, whereby other molecules can be obtained.

The entrance to the assembly is connected to the tubes according to numbers (9) and (10). 30

Polarity code part 4 Lêgêlida: every step is one chip structure with an êèh gêSlótéh circuit. There are 2 poles + êh -, each with 2 different thicknesses. Each line represents a connection with its polarity and with its value.

Stream 1: 2: -1 4: +2 40 6: - 2 8: +1 10: -2 i2: +1 45 Stream 2: 16: +2 18: -2 20: +1 22: -1 8

Stream 3: 5 26: +1 27: +2 28: -1 29: +1 30: +1 10 31: +2 32: -1 33: -2

Stream 4: 15 36: +2 38: -1 40: -2 42: +1 44: +1 20 46: +2

Stream 5: 1: +2 2: -1 25 3: +1 4: +2 5: +1 6: -1 7: +1 30 8: +2 9: -1 10: +1 11: +2 35 12: -1 13: +1 14: +2 15: -1 16: +2 40 17: +2 49: -1 52: +1 55: -1 45 58: +1 61: +1 63: +1 9 65: -1 70: +1 72: +2 74: -1 5 76: +1 78: -1

Stream 6: 81: -1 10 83: +1 85: +2 87: -1 89: +1 91: +2 15 93: +1 95: -1 96: +2 97: +2 20 Section 2 of stream 6: 1: +1 2: -1 3: +1 4: -1 25 5: +1 6: -1 7: +1 8: +2 9: +2 30

Section 3 of stream 6: 1: +1 2: -1 3: +1 35 4: -1 5: -1 6: +1 7: -1 8: +1 40

Section 4 of stream 6: 1: +2 2: +1 3: -1 45 4: -2 5: +2 6: +1 7: -1 8: -2 10

Stream 7: 5 100: +1 102: -2 104: -1 106: -2 108: +2 10 110: +2 112: +1

Stream 8: 118: +1 120: +2 122: -1 124: +1 126: +1 128: +2 130: -1 132: -2

Stream 9: 136: -1 138: +1 140: +2 142: -2 144: +2 146: +1 148: -1 150: -2

Stream 10: 156: -1 35 158: +2 160: +1 162: -2 164: +2 166: +1 40 168: -2 170: +2 172: -2 174: +2 45 Stream 11: 176 : +1 178: -1 180: +1 182: -1 184: +2 186: +1 188: -2 190: +2 192: +2 194: +2 196: -2 10

Stream 12: 1: +2 2: -2 3: +2 15 4: +2 5: +1 6: +1 7: -1 8: -2 20

Stream 13: 1: -1 2: +2 3: -2 25 4: +2 5: -1 6: -2

Stream 14: 30 7: +1 8: -2 9: -1 10: +1 11: +2 35 i2: -2 13: +2 14: +1

Stream 15: 40 15: -1 16: -2 17: -1 18: +1 19: +2 45 20: +1 21: -2 22: +2 12 23: -1

Stream 16: 1: -1 5 2: +2 3: -2 4: +1 5: -2 6: +1 10

Stream 17: 1: +2 2: -2 3: +1 15 4: -1

Ström 18: 1: +2 2: -1 20 3: -2 4: +1 5: +1 6: +2 25 Stream 19: 1: -1 2: +1 3: -1 4: +1 30

Stream 20: 126: +1 128: +2 130: -1 35 132: -2

Stream 21: 1: -1 2: -2 40 3: +2 4: +1 5: -2 6: +1 7: -2 45 8: +2 9: +1 10: -1 11: +2 13

Stream 22: 16: +2 18: -2 20: +1 22: -1

Stream 23: 10 26: +1 27: +2 28: -1 29: +1 30: +1 15 31: +2 32: -1 33: -2

Polarity code part 5. square 20

Step 1: 1: +2 2: +1 3: -1 25 4: -2 5: +1 6: -1 7: -2 30 Step 2: 1: +2 2: +1 3: -2 4: +2 35 5: +1 6: -2 7: +2

Step 3: 40 1: +1 2: +2 3: ^ 2 4: -1 45 Step 4: 1: + 1 14 2: +2 3: -2 4: +1 5: +2 5

The other side:

Step 1: 1: -2 10 2: +1 3: -2 4: +2 5: -2 6: -1 15 7: -2 8: +1 9: -2 10: -2 20 Step 2: 1 : -2 2: +1 3: -2 4: +2 25 5: -2 6: -1 7: -2 8: +1 30 Step 3: 1: +1 2: +2 3: -2 4: +1 35

Step 4: 1: -1 2: -1 3: -2 40 4: -1 5: -2

Variation: 45 Step 1: 1: +2 2: +1 15 3: -1 4: -2 5: +1 6: -1 5 7: -2

Step 2: 8: -2 9: +1 10 10: -2 11: +2 12: -2 13: -1 14: -2 15 15: +1

Step 3: 1: +1 2: +2 3: -2 3: +1

Step 4: 1: -1 25 2: -1 3: -2 4: -1 5: -2 30 Other side:

Step 1: 1: +2 2: +1 35 3: -1 4: -2 5: +1 6: -1 7: -2 40

Step 2: 1: -2 2: +1 3: -2 45 4: +2 5: -2 6: -1 16 7: -2 8: +1

Step 3: 5 1: +1 2: +2 3: -2 4: -1 10 Step 4: 1: -1 2: -2 3: -2 4: -1 15 5: -2

Step 5: 1: -2 2: -2 2Ö 3: -2 4: +2

Step 6: 1: -2 25 2: +1 3: -2 4: +2 5: -2 6: -1 30 7: -2 8: +1 9: -2 10: -2 35 Polarity code for item 6 hexagonal

Step 1: 1: +2 2: +1 40 3: -1 4: -2 5: +1 6: -1 7: -2 45

After step 1 for hexagonal: i? 1: -1 2: +1 3: +2 4: -2 5 5: -2

Step 2: 1: +2 2: +1 10 3: -2 4: +2 5: +1 6: -2 7: +2 15

Step 3: 1: + 1 2: + 2 3: -2 20 4: -1

After step 3 for hexagonal: 1: + 1 2: -1 3: -2 4: -1 5: -2

Step 4: 30 1: +1 2: +2 3: -2 4: +1 5: +2 35

The other side:

Step 1: 1: -2 40 2: +1 3: -2 4: +2 5: -2 6: -1 45 7: -2 8: +1 9: -2 18 10: -2

After step 1 before hexagonal: 1: -1 5 2: +1 3: +2 4: -2 5: -2 10 Step 2: 1: -2 2: +1 3: -2 4: +2 5: -2 6: -1 1. -2 8: +1 20 Step 3: 1: + 1 2: + 2 3: -2 4: + 1 25

After step 3 for hexagonal: 1: +1 2: -1 3: -2 4: -1 5: -2

Step 4: 1: -1 35 2: -1 3: -2 4: -1 5: -2 40 7 Compounds

The body of the assembly is formed by part (1). This consists of two parts and it has a pivot point on one side through which it can open and close. It is also provided with a lever with which the hull can be opened and closed manually.

i9

Subsequently, the reservoirs of the chip structures (4,5, 6} are connected to each other via the tubes (9,10), all reservoirs are inserted into the hull and attached to the screw holes, on the protrusions, to the hull inside.

The tubes (9, 10 are connected to each other with a standard screw and bolt system.

The sensors (7) are attached at the bottom to the screw holes on the hull (1).

10

After attachment of the reservoirs (4,5,6), the filter is screwed to the protrusions and screw holes. The tubes (10) are inserted in the filter in such a way that no leakage can occur. This is placed at the top, so that the two large tubes of the filter form the entrance.

15

The air pressure valve and the pressure filter (Ü, 12) are screwed to the screw holes.

The filter (8) is first attached to the hull at the screw holes, then the tubes are inserted into the input and output. The tubes (10) are attached via a standard screw system. The filter also has this screw system.

The power cables of the chip structures (4,5,6) and the sensors (2,7) are connected to the input and output of the controller.

25

The controller (3) is screwed on the body (1) at the connection points.

When pressure gauges (or barometers) (14) are placed, a wire connection is drawn from the controller (3) to these gauges. The controller is also supplied with power via a plug input for a power cable.

30

The pressure gauges (or barometers) are screwed to the body (1) on the outside of the screw holes.

8 Figure 35

Figure 1: 1 body 2 chip structure with reservoir 3 ditto 40 4 ditto 5 sensor 6 filter 7 tube 8 tube 45 9 input 10 output 11 pressure filter 1039530

Claims (2)

1 ionization element, characterized in that it relates to an apparatus that separates molecules via a chemical process and forms new molecules, the basis of the construction being formed by a hull (1) with input and output, this is preferably made of PVC so that the outer wall (1) is formed of material that prevents discharge or overvoltage, the hull is for safety and to connect the various elements firmly in a larger whole, chip structures with reservoirs (4,5,6) are screwed to the junction points of the hull, previously the reservoirs are connected to tubes (9), the tubes are made of plastic, the sensors are attached to the outside of the hull (2,7) by screwing them, these are for taking measurements, these are connected to the controller (3) via a wire connection that can pass the data to an external element, the reservoirs of the chip structures according to number (5,6) are connected to each other via tubes 15 (10) by joining them together slide and screw on, the tubes also connect the filter (8) that is placed between them, the inlet and outlet is an opening on the hull [1] and forms the components (11,12), the outlet (12) has an air pressure valve that opens at a certain pressure through which liquid or gas can be withdrawn from the composite, the composite has at its outlet a second tube on which a pressure filter (13) is placed which causes the liquids or gases to flow at a certain pressure, both [12 and 13] are attached to the tubes [10] by turning them on the tubes, and optionally pressure gauges (14) are placed and connected to the controller (3) via a wire connection, characterized in that a device is manufactured which decomposes molecules via electrolysis and forms new molecules for both liquids and air parts via a filter system and a chemical process. 2. A ionizing element according to claim 1, characterized in that the hull (1) has two separate parts, the top side has a hinge and handle through which it can open and close. 3. The ionization element according to claim 1, characterized in that the body (1) has a ratio of 42.58 vertically and 107.56 horizontally. 4. Ionizing element, according to claim 1, characterized in that on the upper side of the hull (1) there are hexagonally shaped cavities for air extraction. Ionizing element according to claim 1, characterized in that the controller (3) has a fuse that melts in the event of overvoltage. The ionization element according to claim 1, characterized in that the number of chip structures next to each other, according to number (4), determine how many connections the product that will be produced in element 6 will have. 45. Ionization element according to claim 1, characterized in that each chip structure (4, 5,6) has a separate water reservoir which are connected to each other via tubes (9, ij at the bottom. 1039530 Ionization element, according to claim 1, characterized in that the sensors (2, 7) transmit signals via the controller (3) to an external device or to the manometers (14). in that the reservoirs of the chip structures (4,5,6) are separated from each other and are connected at the bottom by the tubes (9). The ionizing element according to claim 1, characterized in that the chip structures (4, 5, 6) have resistors that burn out a portion of the surplus energy, which burn through at a certain heat 11. Ionizing element, according to claim 1, characterized in that at the transition from a plus to a minus pole the electric wire is open is left so that it remains in contact with the water. 12. A ionizing element as claimed in Claim 1, characterized in that a metal triangular shape 20 is attached to the current wire in order to realize a counterforce, thereby creating a chip structure. Ionizing element according to claim 1, characterized in that the chip structure according to (5) relates to a structure that causes the atoms to move together in a square winding movement. The ionization element according to claim 1, characterized in that the chip structure according to (6) causes the atoms to bind to each other with six connections, whereby a hexagonal connection is established. The ionization element according to claim 1, characterized in that the triangular shapes forming the chip structures (4> 5.6) form a total angle of 171 degrees on a scale of 342 degrees in total for a circular motion. Electrolysis element according to claim 15, characterized in that it is possible to optionally choose to replace the triangular shapes with thyristors and diodes. 17. Ionization element according to claim 1, characterized in that each chip structure is a power connection, which in each case forms a power circuit. Ionizing element according to claim 1, characterized in that the sensors (2, 7) can be replaced according to type and wish. 19. Ionization element, as claimed in claim 1, characterized in that the filter (8) has a ratio of 42.58 vertically and 107.56 horizontally. Ionizing element according to claim 1, characterized in that the filter (8) has a metal wire connection. Ionizing element, according to claim 1, characterized in that the filter (8) has an ocellan-shaped outlet required for filtration. The ionizing element according to claim 1, characterized in that the tubes (9, 10) have a screw system for connecting them to each other and to the different elements. 23. Ionization element according to claim 22, characterized in that the screw system is used for connections between the elements (4, 5,6, 8,9,10,11,12,13). 24 Ionizing element, according to claim 1, characterized in that the air pressure valve of the outlet (12) is optionally replaced by a manually operable valve which can make the outlet open and closed. A 1039530