KR101548463B1 - Output frequency signals control appratus for high-frequency operating apparatus - Google Patents

Abstract

Disclosed in the present invention is an output frequency controlling apparatus for a high frequency operating apparatus, which detects a voltage of high frequency output from a body of the high frequency operating apparatus, and a phase of a current returned through a tissue to be operated, enables a frequency change proper to the tissue through the detected information, and is configured to output high frequency through the changed frequency. Accordingly, the apparatus applies a power a patient wants to tissue to be operated through frequency resonance by considering a capacity and inductivity impedance existing in the tissue, and not only effectively controls bleeding of a part of the tissue when cutting the tissue in a surgical operation, but also reduces the operation time while preventing damages on tissues around the tissue to be operated.

Description

TECHNICAL FIELD [0001] The present invention relates to an OUTPUT FREQUENCY SIGNALS CONTROL APPARATUS FOR HIGH FREQUENCY OPERATING APPARATUS,

The present invention relates to a high frequency surgical instrument, and more particularly, to a high frequency surgical instrument, and more particularly, to a high frequency surgical instrument which includes a high frequency voltage output from a main body of a high frequency surgical instrument in consideration of capacitive and inductive impedances present in a tissue to be treated, And an output frequency control device of a high frequency surgical instrument for varying a frequency to be suitable for a tissue to be treated and outputting a high frequency through a variable frequency so that a power desired by a practitioner can be applied to a tissue to be treated through frequency resonance will be.

Generally, a high-frequency surgical instrument used for surgical operations such as laparoscopic, thoracoscopic, and hemorrhoids constitutes a main body, an electrode, and a large electrode plate as disclosed in Patent Registration No. 10-1039111. In the case of performing a surgical operation It is an indispensable medical device for surgical operations used to incise a part of the tissue to be treated and to reduce bleeding during surgery.

That is, the conventional high-frequency surgical instrument is a device for reducing the incision or bleeding of the tissue to be treated using high-frequency waves, and it can be used for a rapid operation, minimizing the damage of the bloodless tissue, surrounding tissue, and the blood vessel nodule, At the same time, recovery of the tissue site to be treated has a rapid advantage, so that the electrical energy can be converted from a converter to a high-frequency output and then applied to a living tissue.

However, in the conventional high frequency surgical instrument, the output value of the high frequency applied to the target tissue through the electrode has weakened because of the capacitive and inductive impedances existing in the tissue to be treated, In addition, it is difficult to control hemorrhage when incision is made in a part of the tissue to be treated.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method and apparatus for detecting a phase of a high frequency voltage output from a main body of a high frequency surgical instrument and a current refluxed through a tissue to be treated, And a high frequency output is performed through a variable frequency so as to allow the operator to apply the desired power to the target tissue through the frequency resonance in consideration of the capacitive and inductive impedances existing in the tissue to be treated The present invention provides an output frequency control device for a high frequency surgical instrument which can effectively control hemorrhage at incision in a part of a tissue to be treated by performing a surgical operation and can shorten a procedure time while preventing tissue damage around the tissue to be treated That is the purpose.

According to another aspect of the present invention, there is provided an apparatus for controlling an output frequency of a high frequency surgical instrument, the apparatus comprising: a main body for outputting a high frequency; an electrode for transmitting a high frequency output from the main body to a target tissue; Wherein the main body detects a phase of a voltage and a current of a high frequency which is changed according to the capacitive and inductive impedances existing in the tissue to be treated, A phase detector for outputting first and second voltage conversion values of a constant level; Outputting a frequency control signal for adjusting the output intensity of the high frequency according to the first and second voltage conversion values of a constant level output from the phase detector so that a high frequency having the same voltage and current phases is applied to the tissue to be treated through the electrode ; A frequency variable unit for varying a frequency according to a frequency control signal output from the control unit; And a frequency output unit for outputting a high frequency having an output intensity having the same voltage and current phase to the electrode according to a frequency variable in the frequency variable unit; .

The phase detector may further include a first low voltage control unit that receives an output voltage of the high frequency that is output to the electrode from the frequency output unit and varies according to the capacitive and inductive impedances existing in the tissue to be treated, Equivalent circuit; A first comparator for converting and outputting a sinusoidal wave of a low voltage frequency down from the first low voltage equivalent circuit to a first square wave of a constant level; A second low voltage equivalent circuit unit that feeds back a high frequency output current that is changed in accordance with the capacitive and inductive impedances existing in the tissue to be treated while being returned to the electrode plate through the tissue to be treated, A second comparator for converting and outputting a sine wave of a low voltage frequency down from the second low voltage equivalent circuit to a second square wave of a constant level; A phase comparator for comparing the phase differences of the first and second rectangular waves converted and output through the first and second comparators and outputting and controlling the first and second rectangular waves having the phase differences compared; A first smoothing circuit for converting the first square wave whose phase is compared with the output of the phase comparator and whose output is controlled to a first voltage conversion value of a predetermined level and outputting the converted first voltage conversion value to the control unit for adjusting the output intensity of the high frequency; And a second smoothing circuit for converting the second square wave whose phase is compared with the output of the phase comparator and whose output is controlled to a second voltage conversion value of a predetermined level and outputting the converted second voltage conversion value to the control unit for adjusting the output intensity of the high frequency. .

The frequency variable unit may be a PLL (Phase Locked Loop) or a VCO (Voltage Controlled Oscillator).

As described above, the present invention detects the phase of the high-frequency voltage output from the main body of the high-frequency surgical instrument and the current refluxed through the tissue to be treated, adjusts a frequency variable suitable for the tissue to be treated through the sensed information, Frequency power through the resonance frequency, and by applying the desired power to the target tissue through the frequency resonance in consideration of the capacitive and inductive impedances existing in the tissue to be treated, It is possible to effectively control hemorrhage at the incision of a part of the target tissue and to shorten the procedure time while preventing tissue damage around the target tissue.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of an output frequency control apparatus for a high frequency electrode according to an embodiment of the present invention. FIG.
2 is a block diagram of a phase detector according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a block diagram of an output frequency control apparatus for a high-frequency oscillator according to an embodiment of the present invention, and FIG. 2 is a block diagram of a phase detector according to an embodiment of the present invention.

1 and 2, an apparatus for controlling an output frequency of a high-frequency surgical instrument according to an embodiment of the present invention includes a main body 100 for outputting high-frequency waves, a high- A and an electrode plate 300 for returning a high frequency applied to the tissue to be treated A to the main body 100 from the electrode 200, 100 includes a phase detector 10, a control unit (CPU) 20, a frequency variable unit 30, and a frequency output unit 40.

The phase detector 10 detects a phase of a high frequency voltage and a current to be varied in accordance with the capacitive and inductive impedances existing in the tissue to be treated A, The first comparator 12, the second voltage equalizing circuit 13, the second comparator 14, the phase comparator 14, the second comparator 14, (15), and first and second smoothing circuit portions (16) and (17).

The first low voltage equivalent circuit part 11 outputs the output voltage of a high frequency which is output from the frequency output part 40 to the electrode 200 and changes according to capacitive and inductive impedances existing in the tissue to be treated A, And outputs the resultant to the first comparator 12. The first comparator 12 compares the output voltage of the first comparator 12 with the voltage of the second comparator 12,

The first comparator 12 is configured to convert a sinusoidal wave of a low voltage frequency down from the first low voltage equivalent circuit part 11 to the phase comparator 15 by a first square wave having a constant level (e.g., 5 V) will be.

The second low-voltage equivalent circuit part 13 is connected to the electrode plate 300 through the treatment target tissue A, and the second low-voltage equivalent circuit part 13 receives the output of the high frequency wave, which changes in accordance with capacitive and inductive impedances existing in the tissue A to be treated, And after the current is fed back, it is supplied to the second comparator 14 after the current is fed back to the low voltage.

The second comparator 14 is configured to convert the sinusoidal wave of the low voltage frequency down from the second low voltage equivalent circuit part 13 to the phase comparator 15 by a second square wave having a constant level (e.g., 5 V) will be.

The phase comparator 15 compares the phase differences of the first and second rectangular waves converted and output through the first and second comparators 12 and 14 and outputs the first and second rectangular waves, 1 and 2 smoothing circuit units 16 and 17, respectively.

That is, the first square wave converted by the first comparator 12 is input to the input terminal R of the phase comparator 15, and the second square wave converted and outputted by the second comparator 14 is input to the phase comparator 15, The phase comparator 15 compares the phase difference of the first and second rectangular waves and outputs the first square wave through the output stage U1 if the phase of the input stage R is fast. Output control is performed on the first smoothing circuit unit 16 and the second square wave is controlled to be output to the second smoothing circuit unit 17 through the output stage D1 when the input stage V has a high phase.

The first smoothing circuit 16 converts the first square wave whose phase is compared and controlled in output from the phase comparator 15 into a first voltage conversion value V1 of a predetermined level and then adjusts the output intensity of the high frequency To the control section (20).

The second smoothing circuit 17 converts the second square wave whose phase is compared with the output of which is controlled by the phase comparator 15 and is controlled to a second voltage conversion value V2 of a predetermined level and then adjusts the output intensity of the high frequency To the control section (20).

The control unit 20 controls the electrode 200 to apply a first and a second voltage conversion values of a constant level output from the phase detector 10 so that a high frequency having the same voltage and current phases is applied to the tissue to be treated A, And outputs a frequency control signal for adjusting the output intensity of the high frequency to the frequency variable unit 30 according to the voltage V1 (V2).

The frequency variable unit 30 varies a frequency according to a frequency control signal output from the control unit 20. The frequency variable unit 30 includes a phase locked loop (PLL) And a voltage controlled oscillator (VCO).

The frequency output unit 40 is configured to output a high frequency having a voltage and a current of the same output intensity to the electrode 200 according to a variable frequency of the frequency variable unit 30. [

1 and 2, in the apparatus for controlling the output frequency of the high frequency surgical instrument according to the embodiment of the present invention, the electrode 200 of the high frequency surgical instrument is brought into contact with the tissue to be treated A, A high frequency is applied from the main body 100 to the electrode 200.

That is, when a part of the tissue to be treated A is cut by performing the surgical operation in the control unit 20 in the main body 100, a high frequency is applied to the electrode (not shown) through the frequency variable unit 30 and the frequency output unit 40 200, and the high frequency applied to the electrode 200 is returned to the electrode plate 300 through the tissue to be treated A.

At this time, when a high frequency is applied to the electrode 200 and the high frequency is refluxed to the electrode plate 300 via the tissue to be treated A, the tissue to be treated A is subjected to capacitive and inductive impedance The intensity of the applied high frequency can not but weaken.

The first low voltage equivalent circuit part 11 included in the phase detector 10 connected between the frequency output part 40 and the electrode 200 is connected to the electrode 200 through the frequency output part 40 And outputs the high frequency output voltage to the first comparator 12 after feeding back the output voltage of the high frequency which changes according to the capacitive and inductive impedances existing in the tissue to be treated A while being output to the low voltage.

The second low voltage equivalent circuit unit 13 included in the phase detection unit 10 connected between the frequency output unit 40 and the electrode plate 300 is connected to the electrode plate 300 And feeds back the high frequency output current which is changed in accordance with the capacitive and inductive impedances existing in the tissue to be treated A to be fed back to the second comparator 14 after being fed back to the low voltage.

Then, the first comparator 12 converts the sine wave of the low voltage frequency down from the first low voltage equivalent circuit part 11 into a first square wave of a certain level (for example, 5 V) and outputs it to the phase comparator 15 And the second comparator 14 converts the sine wave of the low voltage frequency down from the second low voltage equivalent circuit part 13 into a second square wave of a certain level (for example, 5 V) and outputs it to the phase comparator 15 .

Accordingly, the phase comparator 15 compares the phase differences of the first and second rectangular waves converted and output through the first and second comparators 12 and 14, and outputs the first and second square waves, Output control is performed to the first and second smoothing circuit units 16 and 17.

That is, the first square wave converted by the first comparator 12 is input to the input terminal R of the phase comparator 15, and the second square wave converted and outputted by the second comparator 14 is input to the phase comparator 15, The phase comparator 15 compares the phase difference of the first and second rectangular waves and outputs the first square wave through the output stage U1 if the phase of the input stage R is fast. And outputs the second square wave to the second smoothing circuit 17 through the output stage D1 if the phase of the input stage V is fast.

The first smoothing circuit 16 converts the first square wave whose phase is compared with the output of the phase comparator 15 and whose output is controlled to a first voltage conversion value V1 of a predetermined level, While the second smoothing circuit 17 converts the phase of the second square wave whose phase is compared and controlled by the phase comparator 15 into a second voltage conversion value V2 of a predetermined level, .

Then, the controller 20 adjusts the output intensity of the high frequency according to the first and second voltage conversion values V1 and V2 of the constant levels output from the first and second smoothing circuit units 16 and 17, respectively And outputs the frequency control signal to the frequency variable unit 30.

That is, when the input first and second voltage conversion values V1 and V2 are all at the high level and reach the maximum value, the control unit 20 outputs the voltage The frequency control unit 30 repeatedly outputs the frequency control signal to the frequency variable unit 30 until the high frequency is applied, and the frequency variable unit 30 varies the frequency according to the repeated frequency control signal.

When the frequency output unit 40 outputs a high frequency having the same output voltage to the electrode 200 as the voltage and current phases from the frequency variable of the frequency variable unit 30 to the frequency variable unit 30, The frequency variable of the operation is stopped. Thus, by performing surgical operation, it is possible to effectively control hemorrhage when a part of the tissue to be treated is incised, as well as to shorten the procedure time while preventing tissue damage around the tissue to be treated.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be easy to understand. It is also to be understood that the technical spirit of the invention is also deemed to belong to the scope of the appended claims if the practice of such improvements, alterations, substitutions or additions falls within the scope of the appended claims.

10; A phase detector 11; The first low-voltage equivalent circuit
12; A first comparator 13; The second low voltage equivalent circuit portion
14; A second comparator 15; Phase comparator
16; A first smoothing circuit portion 17; The second smoothing circuit portion
20; A control unit 30; Frequency variable portion
40; Frequency output unit 100; main body
200; Electrode 300; Large plate

Claims (3)

An electrode for transmitting a high frequency output from the main body to a tissue to be treated, and an electrode plate for returning a high frequency to the main body of the electrode to the main body,
The main body detects a phase of a high frequency voltage and a current which are changed in accordance with the capacitive and inductive impedances existing in the tissue to be treated and detects the first and second voltage conversion values of a certain level according to the detected voltage and current phase A phase detector for outputting the phase error signal; Outputting a frequency control signal for adjusting the output intensity of the high frequency according to the first and second voltage conversion values of a constant level output from the phase detector so that a high frequency having the same voltage and current phases is applied to the tissue to be treated through the electrode ; A frequency variable unit for varying a frequency according to a frequency control signal output from the control unit; And a frequency output unit for outputting a high frequency having an output intensity having the same voltage and current phase to the electrode according to a frequency variable in the frequency variable unit; / RTI >
The phase detector includes a first low-voltage equivalent circuit unit for outputting a high-frequency output voltage, which is output to the electrode at the frequency output unit and varies according to the capacitive and inductive impedances existing in the tissue to be treated, ; A first comparator for converting and outputting a sinusoidal wave of a low voltage frequency down from the first low voltage equivalent circuit to a first square wave of a constant level; A second low voltage equivalent circuit unit that feeds back a high frequency output current that is changed in accordance with the capacitive and inductive impedances existing in the tissue to be treated while being returned to the electrode plate through the tissue to be treated, A second comparator for converting and outputting a sine wave of a low voltage frequency down from the second low voltage equivalent circuit to a second square wave of a constant level; A phase comparator for comparing the phase differences of the first and second rectangular waves converted and output through the first and second comparators and outputting and controlling the first and second rectangular waves having the phase differences compared; A first smoothing circuit for converting the first square wave whose phase is compared with the output of the phase comparator and whose output is controlled to a first voltage conversion value of a predetermined level and outputting the converted first voltage conversion value to the control unit for adjusting the output intensity of the high frequency; And a second smoothing circuit for converting the second square wave whose phase is compared with the output of the phase comparator and whose output is controlled to a second voltage conversion value of a predetermined level and outputting the converted second voltage conversion value to the control unit for adjusting the output intensity of the high frequency. Wherein the output frequency of the high-frequency oscillator is controlled by the oscillator. delete The method according to claim 1,
Wherein the frequency variable unit is any one of a phase locked loop (PLL) and a voltage controlled oscillator (VCO).

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