RU136271U1 - PLASMOTRON - Google Patents

Abstract

1. The plasma torch, designed primarily for exposure to biological tissue, comprising a housing located in the housing of the plasma generator, to the output of which is connected an electrode mounted with the possibility of direct exposure to plasma on the tissue, characterized in that the electrode is placed in the opening of the housing with the formation of a gap from 0 , 01 cm to 10 cm between it and the surface of the biological tissue, while the body and biological tissue form a closed conductive circuit, and the magnitude of the voltage pulses is from 1 kV to 100 kV at telnosti from 0.1 ns to 1000 ns.2. The plasma torch according to claim 1, characterized in that the plasma generator is located outside the housing with the possibility of applying voltage pulses through a coaxial cable. The plasma torch according to claim 1, characterized in that the electrode is made of conductive materials. The plasma torch according to claim 1, characterized in that the electrode is coated with a dielectric. The plasma torch according to claim 1, characterized in that the electrode is isolated from the housing by a dielectric gasket. The plasma torch according to claim 1, characterized in that the gap between the electrode and the surface is formed with the possibility of adjustment due to an additional set of gaskets.

Description

The utility model relates to the technique of electric discharges in gases, in particular to devices for generating plasma flows, and can be used in plasma technologies, medicine, and sources of cold plasma.

Plasmatrons - generators of low-temperature dense plasma - have found the widest application in various fields of human activity, due to their unique properties and capabilities.

In physics, plasma refers to a partially or fully ionized gas formed from neutral atoms (or molecules) and charged particles (ions and electrons).

The most important feature of a plasma is its quasineutrality, which means that the bulk densities of positive and negative charged particles from which it is formed are almost the same.

The word "ionized" means that at least one electron is separated from the electron shells of a significant part of the atoms or molecules. The presence of free electric charges makes the plasma a conducting medium, which leads to its noticeably greater (compared with other aggregate states of matter) interaction with magnetic and electric fields.

Gas ionization and plasma formation require significant energy expenditures. The source of this energy can be thermal energy, for example, high-temperature chemical reactions (combustion), electric energy realized in various forms of electric discharges, electromagnetic radiation energy, kinetic energy of accelerated particle flows (electrons, ions, etc.).

The most common sources of plasma are electric discharges, in which plasma is heated by the interaction of charged plasma particles with an electromagnetic field.

Depending on the forms of the electric discharge realized in the generator for plasma production, electric arc, high-frequency, and microwave plasmatrons are distinguished, as well as generators on electromagnetic oscillations of the optical frequency range — optical discharges and high-energy particle flows — a beam discharge.

The inventive utility model relates to electric arc generators of low temperature (cold) plasma.

A known plasma spraying device is designed to spray a powder or gaseous material onto a substrate surface, including a plasmatron with electrodes (see US patent No. 5332885, H05H 1/34, 1994).

Also known is an electric arc plasma torch designed to treat metal surfaces with a plasma jet, which contains a cooled cathode assembly, a housing that is simultaneously an insulator, and a nozzle assembly with a replaceable insert in which the plasma jet is formed (see GB patent No. 1268843, Н05Н 1/34 , 1972).

However, due to the high temperature of plasma release, these devices are unsuitable for use on living tissues of biological objects.

The main difference between cold plasma and other types is the temperature close to the temperature of biological objects, which allows the use of this type of plasma in medicine.

The main uses of plasma in medicine are based on the temperature effects of plasma. High temperature is used in medicine to remove tissues, sterilize and stop bleeding, and cold plasma is used for surgical operations and beauty parlors.

Most research and applications in the field of cold plasma can be divided into two broad categories: direct exposure to plasma and indirect.

With direct exposure, living tissues play the role of one of their electrodes. In most cases, the voltage does not have direct contact with living tissues, although small currents can flow in the form of bias and conductivity currents. Conduction current should be limited to exclude thermal or electrical muscle stimulation. When using direct plasma exposure, the tissue is exposed to a stream of various active charged and uncharged atoms and molecules, as well as ultraviolet radiation.

Known microplasma scalpel-irradiator, including a plasmatron, while the working element is a plasma beam generated as a result of an electric discharge in an inert gas stream (see patent RU No. 2040216, АВВ 17/36, 1995).

The disadvantage of this device is that it is a stationary and technically sophisticated equipment for operating rooms, and also carries out only a “hard” effect that destroys biological tissues.

A plasma needle is known containing an electrode located inside a grounded metal cylinder (see Stoffels, E. et al. Plasma needle: a non-destructive atmospheric plasma source for fine surface treatment of (bio) materials, Plasma Source Sci. Technol, 11, 2002, 383-388).

The specified plasma needle is used to disinfect wounds, however, it is unsuitable for exposure to a large area of the surface, since the outlet of the metal cylinder is very small, only one centimeter.

A physiotherapeutic plasmatron is known, including cathode and anode nodes located in the housing (see patent RU No. 2464747, H05H 1/26, 2012).

This device can be used when performing aseptic and antiseptic effects on soft tissues, as well as stimulating and activating reparative processes on wound surfaces by recombination radiation of a low-temperature inert gas plasma.

This plasmatron has small dimensions, but it is mainly intended for coagulation of blood vessels.

It is known that various electronic waves or electromagnetic waves generated by electric circuits of various electronic devices can cause malfunctions of peripheral electronic devices or their components, degrade the technical characteristics of electronic devices, degrade image quality, creating noise interference, reduce the life of electronic devices or their components and cause malfunctions of electronic products.

To shield such harmful electronic waves and electromagnetic waves, various materials have been developed that shield electronic waves and electromagnetic waves. For example, such materials include metal plates, metallized fabrics, conductive paints, conductive adhesive tapes, or polymer elastomers, which are rendered conductive.

A device for protection against radiation, containing a shell of non-magnetic metal having a grounding contact, and the shell is made with a closed cavity, which is inserted into the device is a high-frequency arc gas discharge device (see patent RU No. 2033200, A61N 1/16, 1995).

This device is a non-magnetic metal shell, which can be both the case of the device and, in this case, must be made rigid. A high-frequency arc gas-discharge device, which can be made on the basis of a gas-discharge lamp, with coaxially mounted electrodes, is placed inside the shell in its closed cavity. The shell has a grounding contact and can be made of aluminum.

The closest in technical essence to the claimed solution is a device for disinfecting surfaces, comprising a housing with an electrode located in it (see patent RU No. 2083227, A61L 2/14, 1997).

This device relates to techniques for disinfection, sterilization and degassing of surfaces of various objects (products, materials, skin and wound surfaces of animals and humans, plant surfaces, etc.) and can be used in medicine, microbiology, cosmetology, animal husbandry and other areas of the national economy .

The disadvantage of this design is that the result of the discharge is electromagnetic interference, which can cause disturbances in the functioning of peripheral electronic devices.

The technical task of the claimed utility model is to create a compact, simple and reliable with repeated use of the plasma torch, which can be used, for example, in the treatment of medical and aesthetic disorders and conditions affecting the skin and subcutaneous tissue of the patient.

The technical result of the utility model is to increase the efficiency of the device by creating a zone that is protected from various radiation.

To achieve the specified technical result in a plasma torch, designed primarily to act on biological tissue, including a housing, a plasma generator located inside the housing, to the output of which is connected an electrode mounted with the possibility of direct plasma exposure to tissue, according to the proposal, the electrode is placed in the hole of the housing with the formation the gap from 0.01 cm to 10 cm between it and the surface of the biological tissue, while the body and biological tissue form a closed conductive circuit, and led The number of voltage pulses ranges from 1 kV to 100 kV with a duration of 0.1 ns to 1000 ns.

According to the proposal, the plasma generator is located outside the housing with the possibility of supplying voltage pulses through a coaxial cable.

According to the proposal, the electrode is made of conductive materials or the electrode is coated with a dielectric and insulated from the housing by a dielectric gasket, and the gap between the electrode and the surface is formed with the possibility of adjustment due to an additional set of gaskets.

The essence of the proposal is illustrated by drawings, where figure 1 schematically shows a General view of the plasma torch, figure 2 shows a cross section of the device.

It should be noted that the drawings show only those details that are necessary for understanding the essence of the proposal, and the accompanying equipment, well known to specialists in this field, is not presented in the drawings.

The plasma torch includes a hollow grounded housing 1 made of metal (Fig.1, 2). Inside the housing 1 there is an electronic unit of the plaza generator 2, to the output of which an electrode 3 is attached, which is installed with the possibility of influencing the biological tissue or other surface by creating an electric discharge between it and the surface.

The electrode 3 is placed in the opening of the housing 1 with the formation of a gap from 0.01 cm to 10 cm between it and the surface of the biological tissue, while the housing 1 and the biological tissue form a closed conductive circuit.

An example of a specific implementation of the device is shown with a plasma generator 2 located inside the housing 1. However, the plasma generator 2 can be placed outside the housing 1 with the possibility of applying voltage pulses through a coaxial cable.

A dielectric strip 4 is placed between the metal housing 1 and the electrode 3 to provide insulation, and the electrode 3 is made of conductive materials or coated with a dielectric, and the gap between the electrode 3 and the surface is formed with the possibility of adjustment due to an additional set of gaskets. For the convenience of changing and holding the electrode 3, magnets 5 are provided.

To ensure the safe operation of the surrounding electronic equipment, a circuit breaker 6 is installed on the surface of the housing 1, which is installed with the possibility of contact with the treated surface.

The plasma gas used is atmospheric air, as well as any other gases.

The plasma torch works as follows.

An operating voltage from 3 V to 50 V is supplied to the input of the plasma generator 2 from a power supply unit or a storage battery (not shown in the drawings). Using power transistors and high-voltage disconnecting switches, high-voltage pulses with an amplitude of 1 kV to 100 kV are generated at the generator output and Duration from 0.1 ns to 1000 ns.

Such voltage pulses applied to two electrodes, namely, electrode 2 and the surface of biological tissue with a gap of 0.01 cm to 10 cm, cause discharge and generation of cold plasma.

When such a plasma stream interacts with biological tissues, protein compounds are not denatured. This allows the surface to be treated directly with a plasma region.

The advantages of the inventive plasma torch are the simplicity of design, compactness, safety and reliability, low penetration when exposed to a plasma stream on biological tissue.

The inventive design of the plasma torch allows you to generate a low-temperature plasma with such parameters that it was possible to carry out a "soft", not leading to destruction, effect on biological tissues. The main factors determining the biostimulating effect of the plasma flow is the biochemical effect of the substances contained in the plasma (in particular NO), as well as intense electromagnetic radiation in the ultraviolet, visible, infrared and submillimeter ranges.

The inventive design of the plasma torch allows you to create a closed volume formed by the housing of the voltage pulse generator and the surface, which is subjected to plasma treatment, which provides both generation and shielding.

The inventive design provides automatic inclusion of the generator in contact with the generator body with the plasma treated surface, which excludes the operation of the generator without the surface to be treated and, accordingly, excludes electromagnetic interference radiation in such a state.

The inventive design allows you to adjust the gap between the potential electrode of the generator and the machined surface due to interchangeable gaskets, adjusting screws, etc.

The inventive design provides a change in the potential electrode for the selection of the desired shape and area, as well as when using magnets holding the electrode.

Claims (6)

1. The plasma torch, designed primarily for exposure to biological tissue, comprising a housing located in the housing of the plasma generator, to the output of which is connected an electrode mounted with the possibility of direct exposure to plasma on the tissue, characterized in that the electrode is placed in the opening of the housing with the formation of a gap from 0 , 01 cm to 10 cm between it and the surface of the biological tissue, while the body and biological tissue form a closed conductive circuit, and the magnitude of the voltage pulses is from 1 kV to 100 kV at telnosti from 0.1 ns to 1000 ns. 2. The plasma torch according to claim 1, characterized in that the plasma generator is located outside the housing with the possibility of applying voltage pulses through a coaxial cable. 3. The plasma torch according to claim 1, characterized in that the electrode is made of conductive materials. 4. The plasma torch according to claim 1, characterized in that the electrode is coated with a dielectric. 5. The plasma torch according to claim 1, characterized in that the electrode is isolated from the housing by a dielectric gasket. 6. The plasma torch according to claim 1, characterized in that the gap between the electrode and the surface is formed with the possibility of adjustment due to an additional set of gaskets.

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