SU1648410A1 - Electrofulgurator - Google Patents

Abstract

The invention relates to medical technology, namely, high-frequency electrosurgery devices, and can be used in dentistry to destroy tissue structures and at the same time obtain stable hemostasis in the trauma zone. The purpose of the invention is to reduce the area of injury and increase the reliability of hemostasis. In order to increase the frequency of spark discharge, the discharge 1 is connected in series with additional capacitors 2 volt additives. This circuit is connected in parallel with the secondary winding of a high voltage source transformer 4. One of the outputs of the discharge 1 is connected to the storage capacitor 5 of the parallel oscillating circuit, and the second output is connected to the choke 3, which is connected to the connection point of the capacitors 5 and 7 of the same circuit. The electrofulgator also reduces the weight and size of the high voltage source. 1 il. gz e qs 4 00 u o

Description

The invention relates to medicine, namely to high-frequency electrosurgery devices, and can be used in dentistry to destroy tissue structures and at the same time obtain stable hemostasis in the trauma zone.

The purpose of the invention is to reduce the area of injury and increase the reliability of hemostasis.

The drawing shows a diagram of the proposed device.

The device contains a spark discharge 1, its leads are connected to capacitors 2 booster in series, and one of these leads is connected to choke 3. This circuit is connected in parallel with the secondary winding of a high voltage source transformer 2. The choke 3 is connected to a storage capacitor 5, which with inductance 6 and the second capacitor 7 form a parallel oscillating circuit. A part of the turns of the inductor 6 is connected to the primary winding of the transformer 8 through the sliding contact 9, and its secondary winding and capacitor 10 form a series oscillating circuit, the beginning of the secondary winding 8 connected to the common wire 11, which in the device performs the functions of a passive electrode. The capacitor 10 is connected to the active electrode 12 through the connector 13 and the cable 14. The primary winding of the transformer 4 is connected to the industrial or lighting power network through the radio interference filter 15 formed by a two-winding choke 16 and capacitors 17. The disconnecting switch 18 and 19 is connected to an on-line network switch that can positioned on the active electrode or on the pedal for foot activation (not shown). The indicator 20 — a high-voltage neon lamp — is connected through a capacitor 21,

When the device is switched on, the secondary winding of the transformer 4 of the high-voltage source, capacitors 2 booster, charge choke 3 and storage capacitor 5 of the parallel oscillating circuit form a series circuit for the transient current. Over time, as the capacitors 2 and 5 are charged, the total voltage across them reaches the voltage level of the secondary winding of the transformer 4, and a higher voltage level is established on the capacitor 5, since its capacitance is lower than that of the capacitors 2. In which point in time, the voltage on the capacitor 5 reaches the level at which the air gap breaks down in the discharge and the spark discharge develops. The conductivity of the spark channel converts the previously existing series circuit into two independent circuits. simye chain, namely arrester 1, capacitors 2 and the secondary winding of the transformer 4, where

capacitors 2 are charged to the voltage level on this winding; discharge 1, choke 3 and capacitor 5, where the discharge of capacitor 5 through choke 3 and the occurrence of oscillatory

process at the resonant frequency of this circuit.

Starting from this point in time, voltages will be applied to the air gap in the discharge, set to

on the capacitors 2 of the voltage booster, and on the storage capacitor 5. Depending on the polarity of their instantaneous values, the level of the resulting voltage contributes to either the development or cessation of the spark. In this case, during the time of action of one half-cycle of alternating current of industrial frequency, conditions are created for the formation of a series of spark discharges, and the energy accumulated in the reactive elements of oscillatory circuits is used to maintain this process.

At the same time in a parallel circuit,

formed by inductance 6 and capacitors 5 and 7, due to the discharge of the storage capacitor 5, an oscillatory process occurs at the resonant frequency of this circuit, and the maximum

The amplitude of the current of the damped high-frequency oscillations in the steady-state mode remains unchanged, since the voltage on the storage capacitor 5 is limited by the maximum breakdown of the air gap in the discharge. Next, a series of damped high-frequency oscillations through the transformer 8, the connector 13, through the cable 14 and the active electrode 12 are introduced into the zone of treated tissue sections. Adjustment

The operating mode of the device is achieved by varying the voltage level supplied to the primary winding of the transformer 8, for which the sliding contact 9 is moved along the turns of the coil 6.

The capacitors 2, in addition to their main function as boost boosters, provide short circuit current limiting in the secondary winding of the transformer 4 in case of an air gap in discharge 1, which favorably affects the thermal regime

work and dielectric strength of high voltage insulating materials, as well as helps to reduce the level of radio interference.

High reliability of the device due to its simplicity, the availability of the element base and the absence of active elements (transistors, thyristors, electronic radio tubes, etc.).

The use of the device makes it possible to reduce the area of injury due to the suppression of the body's response to the action of the electric current of spark discharges and not to resort to anesthesia during fulguration.

In addition, it is possible to reduce the weight and dimensions of the high voltage source, since to increase the voltage level in the air gap in the discharge unit, electric energy is accumulated in the reactive elements of the functional units of the device, as well as by reducing the short-circuit currents of the secondary winding of the transformer during breakdown of the discharge.

Claims (1)

Invention Formula The electrofulgator containing the active electrode, on which the working tool is fixed in the form of a needle, is connected The high frequency shock excitation circuit through a resonant transformer, and the shock excitation circuit, including the discharge and reactive elements of the electric circuit, is connected through a matching circuit to a high voltage source connected to the industrial frequency AC network, characterized in that In order to improve the trauma zone and increase the reliability of hemostasis, the arrester is connected in series with additional booster capacitors, and the circuit is connected allelic secondary a high-voltage source transformer, one of the gaps of the arrester is connected to the storage capacitor of the parallel oscillating circuit, and the other output is connected to a choke connected to the junction point of the capacitors of the same circuit.