RU2526810C1 - Plasma disinfector for biological tissues - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: plasma disinfector comprises a dielectric body with high-voltage and grounded electrode mounted on a surface thereof and spaced at least 50 mm. The body encloses a constant-voltage source and a high-frequency voltage transducer with an output voltage adjuster. A storage capacitor and series commutation switch, loop resistor and pulse transformer an input low-voltage winding of which is connected to the storage capacitor and loop resistor and one of the outputs of an output high-voltage winding of which is connected to a limiting resistor which is connected to a high-voltage electrode, and the other output of which is connected to the grounded electrode, are connected to an output of the voltage transducer. The commutation switch is presented in the form of a gas-filled discharger having a breakdown voltage of 100-1000 V, while a high-voltage electrode is presented in the form of an end-rounded cone with a radius of 2-10 mm.

EFFECT: higher operational stability of the device with uniform and effective disinfectant exposure on a wound surface.

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Description

The invention relates to plasma and medical equipment and can be used to disinfect wound surfaces of biological tissues, as well as stimulate the healing processes.

Known plasma coagulation devices for wound bleeding tissues and blood vessels, which are based on different principles of operation. Most often, these devices use high-temperature plasma of an arc discharge of air or inert gas burning in a jet [1, 2, 3].

The device described in [4] for coagulation and stimulation of the healing of wound defects of biological tissues affects the treated tissue with a low-temperature pulse-periodic discharge plasma. This avoids the harmful effects of high temperature on the workpiece. However, the complex design of the system for supplying working gas to the discharge gap makes it difficult to widely use the device.

A device for disinfecting surfaces by means of a cold plasma [5], which is the closest in terms of the problem to be solved and adopted as a prototype. The known device acts on the processed biological tissue with a low-temperature plasma of a barrier discharge and consists of a small-sized housing in which a constant voltage source, a high voltage AC converter and a high voltage electrode coated with a dielectric layer are placed. Common to the known device and the claimed invention is that the ignited discharge burns in the air and there is no system for supplying the working gas to the discharge gap.

A disadvantage of the known device is the complexity of its design, which can be realized only if the sufficiently high requirements for the electrical and mechanical parameters of the dielectric layer of the high-voltage electrode are met. A significant drawback is the instability of its operation, which leads to poor-quality effects due to the fact that such a complex structure, when the dielectric layer is mechanically or electrically damaged, the discharge immediately changes its structure, and a high-temperature arc is formed in the place of insulation damage, which can even harm the processed biological tissue. In addition, the current of the barrier discharge strongly depends on the capacity of the discharge gap, which in turn is determined by the distance between the high-voltage electrode and the surface to be treated. This instability of the parameters of the plasma of the barrier discharge with a change in distance leads to an inhomogeneous treatment of the surface of the biological tissue.

The technical result of the claimed invention is to simplify the device while increasing the stability of its operation and providing a more uniform and effective disinfecting effect of low-temperature plasma on the wound surfaces of biological tissue. In addition, the technical result of the claimed invention is to reduce the dimensions of the device for the convenience of its "pocket" use, which is especially important for its use in field and / or other extreme conditions (expeditions, mountain transitions, living conditions in sparsely populated areas, etc. ) when emergency assistance is required.

The specified technical result of the claimed invention is achieved by the fact that in the device for disinfecting surfaces by means of cold plasma, comprising a housing made of dielectric material with high voltage and grounded electrodes installed on its surface, the distance between which is at least 50 mm, a constant voltage source placed inside the housing , a high-frequency voltage converter having an output voltage regulator, in accordance with the claimed invention, to output high a frequency converter, a storage capacitor is connected and a switch, a loop resistor and a pulse transformer are connected in series, the input low-voltage winding of which is connected to a storage capacitor and a loop resistor, while the output high-voltage winding of the pulse transformer is connected to one of the outputs with a limiting resistor that is connected to the high-voltage the electrode, and the other with a grounded electrode, the switch is made in the form of a gas-filled azryadnika which has a value of breakdown voltage 100-1000 V and the high voltage electrode has a cone shape with a rounded end at the radius of 2-10 mm.

In the claimed device between the high-voltage electrode and the workpiece, a pulse-periodic discharge is ignited, which is generated during the discharge of the storage capacitor through a series-connected resistor and a pulse high-voltage transformer. The presence of a resistor in the discharge circuit reduces the quality factor of the oscillating circuit formed by the storage capacitor and the pulse transformer. This allows you to reduce the duration of the generated high-voltage pulses and limit the amount of flowing current to safe values.

In addition, this technical result is also achieved by the fact that the discharge process of the storage capacitor is initiated by the breakdown of a series-connected gas discharge switch, which is much more reliable and cheaper than similar semiconductor devices, and the presence of a resistor in the discharge circuit helps to reduce the recovery time of the gas discharge This in turn allows increasing the repetition rate of high voltage pulses up to 1000 Hz and higher.

In addition, the technical result is achieved in that an additional protective resistor is connected in series with the high-voltage electrode.

The essence of the invention is illustrated in Fig.1-Fig.6.

Figure 1 presents a diagram of a plasma disinfector for biological tissues.

Figure 2 shows the dependence of the value of the output voltage on time at a nominal value of the circuit resistance of less than 1 Ω and in the absence of a discharge between the high-voltage electrode and the surface to be treated.

Figure 3 shows the dependence of the value of the output voltage on time at a nominal value of the circuit resistance of less than 1 Ω and in the presence of a discharge between the high-voltage electrode and the workpiece.

Figure 4 shows the dependence of the value of the output voltage on time at a nominal value of the circuit resistance of 15 Ω and in the absence of a discharge between the high-voltage electrode and the treated surface.

Figure 5 shows the dependence of the value of the output voltage on time at a nominal value of the circuit resistance of 15 Ω and in the presence of a discharge between the high-voltage electrode and the treated surface.

Figure 6 shows the dependence of the value of the output voltage on time at a nominal value of the circuit resistance of 1 kΩ and in the absence of a discharge between the high-voltage electrode and the treated surface.

The claimed invention (FIG. 1) comprises a housing (1) made of dielectric material with a high voltage (2) and grounded (3) electrodes installed on its surface, the distance between which is at least 50 mm, and a constant voltage source placed inside the housing (1) 4) equipped with an output voltage regulator (5), a high-frequency voltage converter (6), to the output of which a storage capacitor (7) and a commutator (8), a loop resistor (9) and a pulse transformer are connected in series p (10), the input low-voltage winding of which is connected to the storage capacitor (7) and the loop resistor (9), while the output high-voltage winding of the pulse transformer is connected by one of the outputs to the limiting resistor (11), which is connected to the high-voltage electrode (2), and another output with a grounded electrode (3).

The operation of the claimed invention is as follows.

Power is supplied to the high frequency voltage converter (6). As a result of the operation of the converter, a voltage is excited at its output, the value of which can be from 10 V to 1 kV. The storage capacitor (7) is charged from this voltage to the breakdown voltage of the gas-filled switch (8). After the breakdown of the gas-filled switch (8), a rapidly damping current pulse arises, which excites a high voltage pulse of 3-30 kV at the output of the pulse transformer (10). The output voltage regulator (5) of the high-frequency voltage converter (6) can change the repetition rate of high voltage pulses. As the high-voltage electrode (2) approaches the surface of the treated object, for example, to the skin of a person, a weak discharge lights up, accompanied by a barely noticeable blue-blue glow of cold plasma. In this case, the circuit for the discharge current is formed due to the conductivity of the treated object and the operator who holds this miniature device in his hand. Ultraviolet radiation and plasma components (electrons, ions, excited atoms, molecules and radicals) have a disinfecting effect on the treated surface. If surface treatment is required with an area larger than the contact area of the discharge with the surface being treated, the operator scans over the surface of the object, thereby supporting the “burning” of the plasma.

The claimed invention was tested in laboratory conditions of St. Petersburg State University in real time.

As a result of the experiments, the achievement of the indicated technical result was confirmed: providing a more uniform and effective disinfecting effect of low-temperature plasma on wound surfaces.

Test modes of plasma disinfector for biological tissues.

In all test operating modes of the device, a storage capacitor (7) with a capacity of 10 nF was used, which was charged up to 100 V. The nominal value of the limiting resistance is 15 MΩ. The amplitude value of the output voltage did not exceed 10 kV.

Example 1

The nominal value of the circuit resistance was chosen less than 1 Ω, which corresponds to a very large Q factor of the oscillatory circuit formed by the storage capacitor (7) and the pulse transformer (10). Figure 2 and Figure 3, as mentioned above, presents the dependence of the output voltage on time at a nominal value of the circuit resistance of less than 1 Ω and in the absence of a discharge between the high-voltage electrode and the workpiece (Figure 2) and in the presence of a discharge between a high voltage electrode and a machined surface (Figure 3). In the first case (Figure 2), this dependence shows that the output voltage at a low value of the circuit resistance and the absence of discharge has the form of a slightly damped oscillation, and in the second case (Figure 3), this dependence shows that the output voltage at a low value of the circuit resistance and the presence of a discharge has the form of a strongly damped oscillation.

According to the dependences of the output voltage on time presented in FIG. 2 and FIG. 3, one can see a strong difference in the pulse duration in the presence and absence of a discharge between the high-voltage electrode (2) and the treated surface. This difference is due to the fact that in the presence of a discharge, the quality factor of the oscillating circuit drops sharply.

Example 2

The nominal value of the loop resistance was selected 15 Ω, which corresponds to the quality factor of the oscillating circuit formed by the storage capacitor (7) and the pulse transformer (10) of the order of several units. With this value of the circuit resistance of the claimed device operates most optimally. As mentioned above, in Fig. 4 and Fig. 5, as an example of a specific implementation of the claimed invention, the dependences of the output voltage on time at a nominal value of the circuit resistance of 15 Ω and (Fig. 4) in the absence of a discharge between the high-voltage electrode and the surface to be treated are presented circuit resistance corresponds to the most optimal parameters of the generated high-voltage pulses, and in the presence of a discharge between the high-voltage electrode and the workpiece (Figure 5) osho seen that depending shown in Figures 4 and 5 substantially coincide.

This mode of operation of the device is characterized in that the shape of the generated high-voltage pulse weakly depends on the output current (Fig. 4 and Fig. 5). As a result of experiments at this operating mode of the device, the achievement of the indicated technical result was confirmed. So, for example, after the device exposed to a bleeding wound surface of a small area (several mm ² ), a significant increase in the speed of its healing processes was observed. In addition, the size of a tumor that has arisen, for example, with a bruise (bite), decreased significantly faster when using the device claimed for healing than was usually observed with similar damage to biological tissue by other devices.

Example 3

The nominal value of the loop resistance was chosen 1 Ω, which corresponds to a very low Q factor of the oscillating circuit formed by the storage capacitor (7) and the pulse transformer (10). In this case, the duration of the high-voltage pulse is almost independent of the presence of a discharge between the high-voltage electrode (2) and the treated surface, and is determined by the product of the value of the storage capacitor (7) by the value of the loop resistance. However, with this mode of operation of the device, most of the energy of the storage capacitor (7) is dissipated by the circuit resistance. In the above-mentioned FIG. 6, the dependence of the output voltage on time has the form of an exponential decrease with a maximum value not exceeding several hundred volts.

, где: С - емкость накопительного конденсатора; L- индуктивность первичной обмотки; n~1, что вполне допустимо.In addition to the main mode of operation of the claimed device, of great interest is the mode in which the main current-limiting element is not a limiting resistor (11), but a loop resistor (9). The current in the secondary winding of the pulse transformer cannot exceed the values of U _c / (R · K) (U _c is the voltage of the storage capacitor; K is the transformation coefficient; R is the resistance of the loop resistor). This will require a large value of the resistance of the loop resistor (9) (more than 100 Ω). In order for the quality factor of the oscillatory circuit to remain on the order of several units, it is necessary to use a pulse transformer (10) with a large value of inductance, which in turn will affect its size. With this mode of operation of the device, the duration of the high-voltage pulses will depend on the output current and vary within $$PC\le T\le 2\pi \cdot n\cdot \sqrt{L\cdot C}$$

where: C is the capacity of the storage capacitor; L is the inductance of the primary winding; n ~ 1, which is quite acceptable.

As shown by the results of testing, the claimed device allows you to effectively disinfect wound surfaces of biological tissues in various domestic and extreme conditions, as well as stimulate the healing process in a simple way. Unlike most expensive, bulky and needing a constant source of working gas and mains voltage plasma sterilizers, the claimed device is a small-sized device that can operate on a low-power battery (for example, a small battery or battery).

Of particular importance of the claimed device is a significant simplification, miniaturization, compactness, cheapening compared with known analogues, while increasing stability and ensuring a uniform and effective disinfecting effect on wound surfaces of biological tissue.

List of references

1. Bochkarev S.G .; Volchek S.V .; Gviniashvili G.G .; Danov G.A .; Drozhev V.V .; Kitaev N.P .; Frolov V.N. // electrocoagulator // Patent of Russia RU 2008829, 03.15.1994.

2. Dubinin B.C .; Egoshin E.I .; Kitaev N.P .; Orishchenko V.D .; Frolov V.N. // Method of electrosurgery in hollow organs // Russian Patent RU 2034518, 05/10/1995.

3. Zhuravlev V.N .; Pushin V.G .; Laurent O.B .; Bazhenov I.V. // electrocoagulator // Patent of Russia RU 2080825,10.06.06.1997.

4. Abramov O. I., Nastich Yu. N., Lashchinsky A. G., Khrupky V. I., Pisarenko L. V. // device for coagulation and stimulation of healing of wound defects of biological tissues // Russian Patent RU 2138213, 09/27/1999.

5. Korovin V.N. // device for disinfecting surfaces by means of cold plasma // Russian Patent RU 94038376, 08/10/1996. (Prototype).

Claims (1)

Plasma disinfector for biological tissues, containing a housing made of dielectric material, with high voltage and grounded electrodes installed on its surface, the distance between which is at least 50 mm, a constant voltage source, a high-frequency voltage converter, which has an output voltage regulator, different the fact that a storage capacitor is connected to the output of the high-frequency voltage converter, and a switch, a loop resistor and a pulse transformer are connected in series, the input low-voltage winding of which is connected to a storage capacitor and a loop resistor, while the output high-voltage winding of the pulse transformer is connected to one of the outputs with a limiting resistor, which is connected with a high-voltage electrode, and another with a grounded electrode, the switch is made in the form of gas a filled spark gap, which has a breakdown voltage of 100-1000 V, and the high-voltage electrode has a cone shape with a rounding at the end with a radius of 2-10 mm.

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