ITCE20100007A1 - COLD PLASMA GENERATOR MODULE FOR CHEMICAL-PHYSICAL TREATMENTS ON AIR, GAS AND FUMES, ANY DUCTED - Google Patents

Description

DESCRIPTION OF INDUSTRIAL INVENTION

Description of the industrial invention entitled: "COLD PLASMA GENERATOR MODULE FOR CHEMICAL-PHYSICAL TREATMENTS ON AIR, GAS AND FUMES, HOWEVER CANALIZED ''.

Cold plasma is increasingly used in the textile and chemical industries, as well as in medicine, due to the multiplicity of applications to which it lends itself and the undoubted advantages of this technology. Applications and benefits that increase day by day.

Normally each cold plasma application has its own particular generator designed to optimize performance or to adapt it to the equipment in which it must be inserted.

The cold plasma generator, in its essentiality, consists of a system of electrodes connected to a high voltage source with a 50 or 60 Hertz mains frequency, or a high voltage and high frequency source, or even to a source of only high frequency.

The best known configurations for the electrodes are: A cylindrical condenser; flat condenser. A special dielectric material or just air can be inserted between the electrodes.

Once the electrodes are powered, the cold plasma field is established in the space confined by them

The cylindrical capacitor configuration has a central electrode made of metal filament and an electrode with a solid cylindrical surface. The flow of air, gas or fumes must necessarily cross the electrodes axially. The flat capacitor configuration has a certain number of metal plates connected alternately to one pole and the other of the high voltage and frequency generator. The flow of air, gas or fumes must necessarily cross the plates in a transverse direction. A limitation of these configurations is that they must be made to specific measure of the flow to be treated because it is difficult to make them modular. Therefore each application must have its own cold plasma generator and it is difficult to increase the generator once built, as well as in case of failure the whole generator must be replaced. Furthermore, another difficulty lies in building the electronic voltage and frequency booster circuit. In fact, up to powers of about 100 W this does not present serious difficulties, but for higher powers there are major design and construction problems.

The choice between one and the other configuration is dictated by the application you want to do and the simplicity of installation and maintenance of the generator itself.

The generator according to the present invention is designed for applications of treatments on air, gases and various fumes. The treatments can be the most varied and among these are those of oxidation-reduction, catalysis, formation of chemical radicals, polymerization, depolymerization, simple agglomeration and others.

This cold plasma generator module is characterized by being specifically applied for chemical-physical treatments on air, gases and fumes, however channeled, such as for deodorization and for the purification of process, recirculation or ambient air; to purify fumes in general; to sterilize the air and more; to be mounted on air, gas and fumes ducts or incorporated in specific machines.

Its main features are:

> Unique design.

> Ease of installation,

> Very low single power.

> Unconfined cold plasma field, which then extends beyond the electrodes.

> Possibility of installing a number of generators suitable for the application.

> Independent operation.

> Possibility of increasing the number of generators installed even at a later time.

> Installed in battery, the risk of the entire system being out of service is limited.

In practice, the cold plasma generator of the present invention adopts a scheme with single electrodes arranged in a cylindrical configuration. The central electrode is positioned in the center of the primitive circle on which the other electrodes are placed. On the primitive circle 3 or 4 or more electrodes are then placed so that the distance between each of the electrodes placed on the circle and the central electrode is constant and is equal to the radius of the circle.

In Fig. 1 we see the example of a modular generator with electrode 1 placed in the center of the primitive circle and three electrodes 2 arranged on the circle itself at 120 <®> from each other. The configuration of the electrodes in this example is best seen in Fig. 3.

In Fig. 6 we see instead the example of a modular generator with the electrode 1 placed in the center of the primitive circle and six electrodes 2 arranged on the same circle at 60 ° from each other. The electrode configuration in this example is best seen in Fig. 7

The electrodes 2 consist of an aluminum or copper or steel tube with a diameter of no more than 8 millimeters and a length that can start from a few centimeters and up to a few meters. If electrodes longer than 50 centimeters are used, it is advisable to install spacers 31, as shown in Fig. 10, in electrical insulating material every 50 centimeters, to prevent the electrodes from bending and vibrating when they are crossed by the flow. They can be installed naked or covered with polyolefin or Teflon or silicone sheath with a thickness not exceeding one millimeter, with the function of dielectric and chemical protection. For applications in high fluid temperatures, the electrodes can be coated with glass or ceramic, always of low thickness, having the same dielectric and chemical protection functions, but resistant to high and very high temperatures.

The central electrode 1 can be made like the electrodes 2 or with a metal core with a diameter of less than 6 millimeters, solid or tubular, but always such as to be sufficiently rigid to resist the thrust of the air passing through them.

The electrodes are inserted, kept still and in position on the flange 5 by suitable compression fittings 3 in nylon or other electrical insulating material The terminals of the electrodes are kept firm and in position by the disk 4, always with suitable compression fittings 3 in nylon or other electrical insulating material The arrangement of the electrodes on the flange 5 and on the terminal disc 4 is the same, so that the electrodes are all parallel to each other.

Holes 12 are drilled on the flange 5 for fixing the generator

The distance between the central electrode and the external electrodes can vary from a few millimeters to up to 10 centimeters. This distance is a function of the voltage and frequency supplied by card 8 and also of the intensity of the plasma field to be generated,

The electrical and electronic components necessary for operation are housed in the body 6 which is closed by the flange 5 on one side and by the cover 7 on the other side The power supply cable 11 comes out of the body, held in place and sealed by a suitable compression fitting 3 made of nylon or other electrical insulating material. The two indicator lights of the generator itself are housed on the cover 7, visible in Fig 4. Lamp 9 indicates that the generator is powered by the mains, while lamp 10 indicates that the plasma field is active.

Fig. 2 shows a partial section of the generator itself, in which all the constituent elements are recognized and how the electronic board 8 is arranged in the body 6.

In this section it can also be seen that all the empty space inside the body 6 is filled with special resin 13, with characteristics of high electrical insulation and such as to ensure not only electrical insulation, but also gas and water insulation, for which all the electrical and electronic circuitry is incorporated and made watertight by the resin cast inside.

The flange 5, the terminal disc 4 and the spacer 31 are made of electrical insulating materials, therefore various polymers such as PVC or PE or others or of glass or ceramic, while the body 6 and the cover 7 can be made of electrical insulating materials as said before or also in metallic materials such as steel, aluminum or other. One or the other solution depends on the application that must be done.

Fig. 5 shows the electrical diagram of the modular cold plasma generator.

The power supply line is 220 +/- 30 Volt alternating current or other voltage, 50-60 Hertz and enters terminals 14 and 15, while terminal 16 is for ground connection. Before powering the electronic board 8, for the purposes of protection and operational safety, an electric fuse 17 is inserted to protect against short circuits, an automatic thermostat 18 calibrated at 6Q ° C / - 10X or lower which opens the power supply in case of abnormal heating, a non-resettable thermal fuse 19 calibrated at 90 "C / - 5 <®> C which permanently cuts off the power supply in the event of high temperature and the thermostat not tripping 18

The power supply line thus protected enters terminals 21 and 22 of the electronic board. A further protection consisting of a varistor 20 is inserted between these two terminals to protect it from sudden voltage rises which can occur due to atmospheric discharges during thunderstorms.

The electronic board 8 is a voltage and frequency booster circuit or voltage only or frequency only, with absorbed power not exceeding 100 W

If the board 8 is a voltage and frequency booster circuit, then at the output terminals 23, 24 and 25 there can be a dual voltage that can vary from 2 + 2 kV and up to 20 + 20 kV with a frequency that can vary from 1 kHz and up to approximately 100kHz.

If board 8 is only a voltage booster circuit, then at the output terminals 23, 24 and 25 there can be a dual voltage which can vary from 2 + 2 kV and up to 20 + 20 kV with mains frequency at 50- 60 Hz.

Finally, if the board 8 is only a frequency booster circuit, then at the output terminals 23, 24 and 25 you can have the mains voltage 110-220 V, with a frequency that can vary from 1 kHz and up to about 100 kHz.

The choice between one card 8 and the other is made according to the effects to be created.

Terminal 24 represents the center of the dual voltage and is connected to ground via terminal 16. All external electrodes are connected in parallel to terminal 23, while only the central electrode is connected to terminal 25.

The circuit is completed by the pilot light 9 which is connected on the power supply line downstream of the fuses and the pilot light 10 which is inductively connected to the high voltage-high frequency cable of terminal 23 or 25.

Fig. 11 shows a variant of the electrical diagram, always with the same notations, where the electrode 1 is powered with pulsating unidirectional current. This power supply is obtained by installing a series of high voltage diodes 32 on the dual output. The number of diodes required is a function of the output voltage from terminals 23, 24 and 25 and of the maximum working voltage of each diode. For example, if the output voltage is 10 + 10 kV and each diode can work at a maximum of 4 kV, each series must be composed of at least 4 diodes, thus ensuring a working voltage of 16 kV.

Finally, Fig 8 and Fig. 9 show, purely as an example, an application of eight generators on a duct 26 crossed by a flow of air or gas or fumes in direction 29 or 30. In particular, the simplicity of installing a generic number of generators as well as the simplicity of maintenance and replacement of one or more of them in case of failure.

On one part of the duct it is sufficient to drill the holes 27 with a slightly larger diameter than the terminal disk 4 of the generator and thus insert them and fix them with the flanges to the holes 28. The arrangement of the generators must be taken care of so as to completely cover the cross section of the flow, so that the electrodes are always hit by the flow itself. The flow of air, gas or fumes being treated crosses the generator electrodes transversely to them, undergoing the effect that will trigger the expected reactions. This configuration also has the advantage of offering a limited pressure drop when crossing the flow, so it has little effect on the power needed to move the flow itself. This installation example allows to deliver a power up to 800 W to generate the cold plasma, with single generators of power not exceeding 100 W, therefore easy to build. In installations with more than 20 or 30 modular generators as described in the present invention, it is possible to process significant powers, of the order of kW.

Claims (1)

CLAIMS Description of the industrial invention entitled: "COLD PLASMA GENERATOR MODULE FOR CHEMICAL-PHYSICAL TREATMENTS ON AIR, GAS AND FUMES, HOWEVER CANALIZED". 1- Cold plasma generator module for chemical-physical treatments on air, gas and fumes in any case channeled, characterized by the fact of adopting a scheme with several electrodes arranged in a cylindrical configuration with a central electrode positioned in the center of the primitive circle on which the other electrodes, so that the distance between each of the electrodes placed on the circle and the central electrode is constant and equal to the radius of the circle, thus also being parallel to each other. 2- Generator as per claim 1, characterized by the fact that the electrodes on the primitive circle and the central one are held in position with suitable compression fittings, so that they can be removed and replaced at any time. 3- Generator as in claim 1, characterized in that it has all the electrical and electronic components necessary for its operation in a body which is closed by the electrode-holder flange on one side and by a cover on the other side, with the power supply held firm and sealed by a suitable compression fitting. 4- Generator as in claim 1, characterized by the fact that on the cover there are two indicator lamps for operation of the generator itself. The first lamp indicates that the generator is mains powered, while the second lamp indicates that the plasma field is active. 5- Generator as in claim 1, characterized in that the terminals of the electrodes are held stationary and in position by a terminal disk, always with suitable compression fittings, with the same arrangement of the electrode-holder flange. 6- Generator as in claim 1, characterized in that to maintain the parallelism between the electrodes, if these exceed 50 centimeters in length, it is possible to install intermediate spacer discs in electrical insulating material. 7- Generator as in claim 1, characterized in that the electrodes consist of an aluminum or copper or steel tube with a diameter of no more than 8 millimeters and a length that can start from a few centimeters and up to a few meters. 8- Generator as in claim 1, characterized by the fact that the electrodes can be installed bare or coated with a polyolefin sheath or Teflon or silicone or even glass or ceramic. 9- Generator as in claim 1, characterized by the fact that the electrodes can be supplied with high voltage and high frequency alternating current or only one of the same or with pulsating unidirectional current, according to one of the schemes shown and described in the report.