JPH0634792B2 - Electrosurgical unit - Google Patents

Description

Description: [Industrial application] The present invention relates to an electrosurgical instrument for performing incision / coagulation by high-frequency output power.

[Prior Art] FIG. 4 is a circuit diagram showing a configuration of a conventional electrosurgical instrument such as an electric scalpel. The electrosurgical instrument 10a includes an amplifier 12 for amplifying high-frequency output power. The control unit 14 for controlling the amplification amount of the high frequency output power to a predetermined value and the primary side of the output transformer 16 for further boosting the high frequency output power amplified by the amplifier 12 are connected to the.

Further, an output unit 22 for connecting the high frequency output power boosted by the output transformer 16 to the load impedance ZL (that is, the living tissue to be operated) 20 via the capacitor 18 for removing low frequencies is connected to the secondary side of the output transformer 16. Has been done.

The electrosurgical unit 10a, as shown in FIGS. 5 and 6, has an internal impedance ZS 24 and a load impedance ZL 2 on the device side, that is, on the side of the amplifier 12 and the control unit 14.
It is known that the maximum output power is generated when 0 is matched, and the output power is reduced according to the size of the mismatch when the load impedance ZL 20 is not matched.

Next, the operation will be described.

The amplifier 12 amplifies the high-frequency output power to a predetermined value by a signal from the control unit 14, the high-frequency output power amplified by the amplifier 12 is further boosted by the output transformer 16, and the output unit 22 outputs the living body having the load impedance ZL. Guided by the organization 20.

By the way, in the electrosurgical instrument 10a described above, when the load impedance ZL 20 changes, the output power decreases according to the size of the mismatch between the internal impedance ZS 24 and the load impedance ZL 20 on the device side, and There is a problem that the sharpness of the surgical instrument 10a becomes poor and the surgical instrument 10a gets caught in the living tissue 20.

Therefore, as shown in FIG. 7, there is proposed an electrosurgical instrument 10b including a voltage detector 26 for detecting the voltage of the output unit 22 and a current detector 28 for detecting the current of the output unit 22 (Japanese Patent Application Laid-Open No. 2004-242242). JP-A-58-96292, JP-A-60-72
544 and JP-A-61-124266).

The electrosurgical instrument 10b includes a voltage detector 26 and a current detector 2
The power detection unit 30 detects the output power of the output unit 22 based on the signal of No. 8 and the detection signal of the power detection unit 30 is fed back to the control unit 14.

The power detector 30 is composed of a circuit using a multiplier, an analog-digital converter, a microprocessor, and the like.

Next, the operation will be described.

In the same manner as described above, the high frequency output power is guided to the living tissue 20 having the load impedance ZL by the output unit 22 and the operation is performed. At this time, the voltage detector 26 detects the voltage of the output unit 22, and the current detector 28 detects the current of the output unit 22.

Then, the detection signals of the voltage detector 26 and the current detector 28 are input to the power detector 30, and the power detection unit 30 outputs the output unit 2 according to the detection signals of the voltage detector 26 and the current detector 28.
The output power of 2 is calculated.

Then, the output power of the output unit 22 calculated by the power detector 30 is input to the control unit 14, and the control unit 14 calculates the load impedance ZL 20 by the output power of the output unit 22 calculated by the power detection unit 30, The power amplification factor of the amplifier 12 is adjusted so that the output power decreased by the amount of mismatch between the internal impedance ZS 24 on the device side and the load impedance ZL 20 and the output power becomes constant. .

[Problems to be Solved by the Invention] Since the conventional electrosurgical unit is configured as described above, when a microprocessor or the like is used for the power detector 30, the control speed becomes insufficient and a time lag occurs. There is a risk that unexpected output power may be generated, and since expensive components such as a microprocessor are used, the cost is increased and the device is complicated. Further, when the microprocessor causes a malfunction such as a runaway, it is difficult to sufficiently prepare measures against the malfunction. Further, the output unit 22
The voltage detector 26 and the current detector 28 provided in the above insulate the signal output port, but the labor is troublesome, and if the insulation is incomplete, the stray capacitance is increased by the additional members for these detectors. However, there is a disadvantage that the high frequency leakage current increases.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an electrosurgical instrument that is inexpensive, has good insulating properties, and has good responsiveness.

[Means for Solving the Problems] An electrosurgical instrument according to the present invention is a high frequency power generation source for generating high frequency power, an output transformer for boosting the high frequency power, and high frequency power boosted by the output transformer. An electrode section for performing incision / coagulation of living tissue by means of a comparison impedance, and a deviation detector for detecting a deviation between the load impedance of the living tissue and the comparison impedance, and the high frequency power based on the deviation. It is characterized by controlling.

Further, a high-frequency power generation source that generates high-frequency power, an output transformer that supplies the high-frequency power to a primary winding to boost the high-frequency power, and a secondary winding of the output transformer are connected and boosted. An electrode section for cutting and coagulating living tissue by high-frequency power; a comparison impedance connected to the tertiary winding of the output transformer; a load current flowing through the electrode section and a comparison current flowing through the comparison impedance. A deviation detector for detecting deviation, and controlling high frequency power based on the deviation.

Further, the deviation detector is a differential coil.

[Operation] According to the present invention, the high frequency power generated by the high frequency power generation source is boosted by the output transformer, and the incision / coagulation of the living tissue is performed by the electrode portion to which the boosted high frequency power is supplied. . At that time, the comparison impedance is provided, and the deviation between the load impedance of the living tissue and the comparison impedance is detected. That is, according to the present invention, the load impedance can be detected as a deviation with reference to the comparison impedance. Therefore, it is possible to properly control the high frequency power according to the variation of the load impedance.

Also, by connecting the comparison impedance to the tertiary winding of the output transformer and driving the comparison impedance with a part of the high frequency power, the phases of the secondary side and the tertiary side of the output transformer can be matched. When the high frequency power supplied to the primary side of the output transformer fluctuates, the voltage on the tertiary side can be fluctuated in conjunction with the secondary side. In that case, the difference between the load current and the comparison current is detected as a deviation, and the high frequency power is controlled based on the deviation.

Furthermore, by using a differential coil as the deviation detector, the secondary side of the output transformer can be completely insulated, that is, the insulation of the electrode portion can be maintained when measuring the load impedance.

[Embodiment] An embodiment of the present invention will be described below with reference to the drawings.

The same parts as those described above are designated by the same reference numerals and the description thereof will be omitted.

As shown in FIG. 1, the electrosurgical instrument 10 has an adder 32 between the control unit 14 which is a high frequency output signal generator and the amplifier 12, and the output unit 22 detects impedance deviation. It has a deviation detection voltage generator 34 for performing.

A comparison circuit 36 and a correction amount adjusting device 38 are connected to the deviation detection voltage generating device 34, and the correction amount adjusting device 38 is connected to the adder 32.

Further, the comparison circuit 36 includes a comparison voltage generator 40 and a comparison impedance Zr 42, and the comparison impedance Zr 42 and the load impedance ZL.
It is designed to be compared with 20.

Incidentally, in the electrosurgical instrument 10, as shown in detail in FIG. 2, the deviation detection voltage generating means 34 is constituted by a differential coil, and the comparison voltage generating device 40 is constituted by the primary winding 16a of the output transformer 16 or By using a tertiary winding having a smaller number of turns than the number of turns of the secondary winding 16b, further simplification is achieved, and impedance deviation can be detected while the output unit 22 is reliably floating from the grounded state.

In addition, the correction amount adjusting device 38 includes the smoothing circuit 44 and the amplifying unit 4.
6, the smoothing circuit 48, and the arithmetic unit 50, and the smoothing circuit 44 includes a diode bridge 52, a capacitor 54, and two resistors 56 and 58.

Further, the amplifier 46 is composed of three resistors 60, 62 and 64 and the amplifier 66, and the smoothing circuit 48 is composed of a capacitor 68 and two resistors 70 and 72.

Next, the operation of this embodiment will be described.

The comparison voltage generator 40 constituted by the tertiary winding of the output transformer 16 supplies the comparison current Ir which is not affected by the change of the load impedance ZL 20 to the comparison impedance Zr.
Pour into 42.

Then, the comparison current Ir and the output current IL are passed through the deviation detection voltage generator (hereinafter referred to as a differential coil) 34, and the load impedance ZL 20 and the comparison impedance Zr 42 are passed.
It is detected as a differential voltage between

Then, the detected differential voltage is input to the correction amount adjusting device 38, smoothed by the smoothing circuit 44, amplified by the amplifier 46 at a predetermined amplification factor, and further smoothed by the smoothing circuit 48 to become the deviation voltage Vd, which is the deviation voltage Vd. Arithmetic unit 50
Is processed by.

For example, if the value of the load impedance ZL 20 when the load impedance ZL 20 and the internal impedance ZS 24 on the device side are matched is Z0, the value of the comparative impedance Zr 42 is the output 22 side of the differential coil 34. Is equal to the number of turns on the comparison circuit 36 side, S2
× Z0 / S1 In addition, S1 is the secondary winding 16
The number of turns of b, S2, is the number of turns of the tertiary winding 40.

When the load impedance ZL 20 and the internal impedance ZS 24 on the device side are matched, IL = I
When r and Vd become 0 (see FIG. 3 (c)), and the load impedance ZL 20 increases or decreases,
Output power decreases (see Figure 3 (a)) and Figure 3 (b)
When the electric power is insufficient as shown in FIG. ² and the control voltage Vin ² from the control unit 14 and the electric power P generated by the amplifier 12 can be expressed as P = AVin ² with A as a constant, the deviation voltage Vd at that time is calculated. 50 by being Vd ^2/2 adders 32
Is output to.

Further, the adder 32 adds the voltage obtained by adding Vd ^2/2 from the operation unit 50 to the control voltage Vin from the controller 14 to compensate for the power shortage to input voltage obtained by adding to the amplifier 12.

In the above-described embodiment, the calculation unit 50 performs the predetermined process of the deviation voltage Vd, but the correction amount adjusting device 38 is used.
It is possible to omit the arithmetic unit 50 by selecting an appropriate amplification factor of the amplifier 66 in the unit and changing the ratio of the control voltage Vin from the control unit 14 to the deviation voltage Vd.

Further, in the above embodiment, the load characteristic is controlled to be constant, but the present invention is not limited to this, and the load characteristic may be improved by generating a small deviation voltage Vd.

Further, in the above-described embodiment, the comparative impedance Z
The value of r 42 was calculated by S2 × Z0 / S1, but the value of the comparative impedance Zr 42 is not limited to this.
The correction amount may be intentionally shifted from the value determined by 0 / S1 and the correction amount may be changed depending on whether the load impedance ZL 20 is larger or smaller than Z0.

In the above embodiment, the comparative impedance Z
Although the resistance value of r 42 is fixed, the resistance value of r 42 is not limited to this, and the comparison impedance Zr 42 may be variable.

Further, in the above embodiment, the deviation detection voltage generator 3
Although 4 is composed of a differential coil, the invention is not limited to this, and the current Ir and the output current IL flowing through the comparison circuit 36 may be detected separately by a differential amplifier or the like. If you do this,
It is also possible to change the correction amount depending on the magnitude of the current Ir flowing through the comparison circuit 36 and the output current IL, depending on whether the load impedance ZL 20 is greater than Z0 or smaller.

[Effects of the Invention] As described above, according to the present invention, the load impedance of the living tissue can be detected as a deviation by using the comparative impedance, and as a result, the load impedance can be detected with a simple configuration and accordingly Appropriate high frequency power control can be performed.

Further, according to the present invention, it is possible to ensure the insulation on the secondary side of the output transformer.

As described above, according to the present invention, the load impedance can be accurately measured by the comparative impedance with a simple configuration, whereby quick control can be achieved and cost reduction can be achieved.

[Brief description of drawings]

FIG. 1 is a schematic circuit diagram showing a schematic configuration of an electrosurgical instrument according to the present invention, FIG. 2 is a circuit diagram showing a configuration of an electrosurgical instrument according to the present invention, and FIG. 3 is an operation of the present invention. FIG. 4 is a circuit diagram showing a configuration of a conventional electrosurgical instrument, FIG. 5 is a diagram showing internal impedance on the device side, and FIG. 6 is a load characteristic of the conventional electrosurgical instrument. FIG. 7 is a circuit diagram showing a configuration of a conventional electrosurgical instrument. 10, 10a, 10b ... Electrosurgical instrument 12 ... Amplifier 16 ... Output transformer 22 ... Output section 32 ... Control means (adder) 34 ... Deviation detection voltage generator (differential coil) 36 ... Comparison Circuit 38: Correction amount adjusting device 40: Comparative voltage generator (tertiary winding) 42: Comparative impedance.

Claims (3)

[Claims] 1. A high-frequency power generation source that generates high-frequency power, an output transformer that boosts the high-frequency power, and an electrode section that cuts and coagulates a living tissue by the high-frequency power boosted by the output transformer. An electrosurgical instrument comprising: a comparison impedance; and a deviation detector that detects a deviation between the load impedance of the living tissue and the comparison impedance, wherein the high frequency power is controlled based on the deviation. 2. A high-frequency power generation source that generates high-frequency power, an output transformer that supplies the high-frequency power to a primary winding to boost the high-frequency power, and a secondary winding of the output transformer. , An electrode section for cutting and coagulating living tissue by boosted high-frequency power, a comparison impedance connected to a tertiary winding of the output transformer, a load current flowing through the electrode section, and the comparison impedance. An electrosurgical instrument comprising: a deviation detector that detects a deviation from a comparison current, and controlling high-frequency power based on the deviation. 3. The electrosurgical instrument according to claim 2, wherein the deviation detector is a differential coil.