HU191282B - Device for measuring dangerous currents developed in the course of application of surgical high-frequency cutting and coagulating devices - Google Patents

Abstract

Field of the Invention The present invention relates to a device for measuring the risk currents occurring during the use of surgical high frequency cutting and coagulating devices in which one of the outlets of a high frequency generator (1) is connected to an surgical cutting device, in particular a knife (2) by an active conductor, while another terminal of the high frequency generator (1) is on a neutral conductor. (6) is connected to a neutral electrode (5) placed on the body of a patient (4). The essence of the invention is that the active conductor (2) and the neutral conductor (6) are passed through an orifice (9) made of magnetic material, and a measuring sensor coil (10) is arranged on the ring core (9) (Figure 3). 3.cibrct -1-

Description

FIELD OF THE INVENTION The present invention relates to an apparatus for measuring hazard currents in the use of surgical high frequency cutting and coagulation apparatus, wherein one terminal of a high frequency generator is connected to a surgical cutting device through an active conductor and another to a neutral conductor. High-frequency cutting and coagulation devices have been used successfully in surgical practice for some time. For these. the essence of this is that high frequency current is applied at high current density in the tissue region intended for cutting and coagulation. The occurrence of high current density is only desirable at the site of intervention, so that the return of the returning "collecting" branch, also known as the neutral branch, to the patient is accomplished by a high surface area neutral electrode providing a low current density. Ideally, with a full-surface and low-transition neutral eicklode connection, the magnitude of the high frequency currents flowing in the active and neutral branches is equal.

In practice, even with this ideal connection, it is due to the capacity of the patient operating table. approx. 10% of the cz.en passes through the capacitive shunt. An increase of this 10% current may constitute a danger. Reasons for growth may include:

- a significant increase in the transient resistance of the neutral electrode patient (poor contact); loss of contact, break of the neutral circuit - creation of other parasite prices (eg: a patient's body is in direct contact with a grounded operating table).

Both error states can occur together, increasing the risk of intervention. A common feature of the described error states is that the difference in shunt current between the neutral and active branches increases, the exit point and surface, so the magnitude of the current density is unknown and cannot be controlled.

It is essential to avoid galvanic continuity in the neutral circuit in order to avoid hazards from shunt currents. However, a complete solution is to indicate that the differential current limit is exceeded, since ensuring the continuity of the neutral circuit does not preclude the danger currents from increased transient resistance of the patient-neutral electrode and from accidental contacting of the patient earth.

For high-frequency surgical cutting and coagulation devices in use, the basic technical solution for emergency response, as required by national and international standards, is in the form of an alarm circuit for monitoring the galvanic continuity of the neutral circuit and for failure conditions.

This system has several shortcomings. Neutral Circuit Continuity Check is not suitable for indicating increased resistance between the neutral neutral electrode patient, and therefore the resulting capacitive shunt current (current difference between the neutral and active loops) is not indicated, so the method used so far to develop an emergency it is a necessary but not sufficient condition.

Neutral circuit continuity monitoring is also inappropriate to detect differential currents generated by undesirable direct patient grounding, so the use of this procedure in this case only means meeting the necessary, but not sufficient, condition to avoid (indicate) an emergency.

Among the known solutions, the circuit disclosed in US-PS 4,102,341 detects the quotient of the currents in the active branch and the neutral branch and disables the device when it reaches a certain quotient value. In many respects, this device does not meet the requirements of this device. Disabling deprives the surgeon of the decision to continue surgery to minimize damage. However, the quotient measurement does not show the magnitude of the currents actually flowing through the patient and the operating table to the ground, the magnitude of this current being crucial from a physiological point of view. A further disadvantage of this solution is that it measures the current in the two branches separately and forms a quotient, thus increasing the measurement error.

Another solution, disclosed in US-A-3,885,569, detects the difference in currents in the active branch and the neutral branch by sensing the difference current by winding the two branches onto a toroidal iron core, a third winding. If a current is detected on the third coil, this device will stop when a certain limit is reached. This device requires many components and has complicated wiring, so the potential for failure is high.

It is an object of the present invention to provide a device that simply enables the surgeon to sense the danger and decide whether to continue or discontinue the operation.

The essence of the invention is that the active conductor and the neutral conductor are guided through an orifice made of a magnetic material and a measuring sensor coil is arranged on the annular core.

The invention will be described in more detail with reference to the embodiments shown in the figures;

Figure 1 shows a schematic diagram of the use of a surgical cut tube for coagulation, Figure 2 illustrates an electrical substitution diagram of Figure 1, Figure 3 shows an example of the device according to the invention. mutates its annular nucleus while the

Figure 4 shows another exemplary ring core arrangement.

The high frequency generator 1 shown in Fig. 1 is connected via an active conductor 2 to a knife 3 which performs surgery on a patient 4 with a knife 3. The neutral electrode 5 connected to the patient 4 is connected to the other terminal of the high frequency generator 1 via a neutral conductor 6. Patient 4 is insulated 7 on an operating table 8 which is grounded together with the high frequency generator 1.

191,282

The apparatus of Figure 1 operates as follows:

The current If generated by the high frequency generator 1 through the knife 3 penetrates the patient 4 at a high current density and produces the desired effect in the vicinity of the contact. The current is collected from the body by the neutral electrode 5 and fed back to the high frequency generator 1 via the neutral conductor 6 attached to it. However, only part of the If current phase I _r is returned to this considered to be regular way, and the other part, the I _p hazard current to ground in the four patients for 7 insulation impedance and thus is returned to the grounded one high frequency generator. The critical location is the location of the "exit" of the hazard stream from 4 patients, the extent of the hazard depending on the magnitude and density of the exit hazard stream. ~

The symbols in Figure 2 are as follows:

U _{g is} the voltage of the high frequency generator 1

Z _{g is} the impedance of the generator

Zj is the serial replacement impedance of the active electrode (3 knives) and 2 active leads

Z _{s is} the impedance of 5 neutral electrodes and 6 neutral conductors in series

Z4i where i = 3, 5, 7 are the alternate impedances between the body of the 4 patients and their surrounding environment, such as:

Z ₄₃ between 4 patient body and 3 knives Z45 between 4 patient body and 5 neutral electrodes

Z ₄₇ between patient organization 4 and isolation 7 Replacement impedance of isolation ₇ on operating table 8

Z _{13 is} the impedance impedance between the high frequency generator 1 and ground

It is clear from Figure 2 that the hazard current I _p relative to the If current:

Ip ₌ Z ₅ + Z ₄₅

If Z5 + z ₄₅ + z ₁₃ + z ₇ + z ₄₇ or I _r :

Ip _ Z _s + z ₄₅ I _r Z ₇ + Zi3 + Z ₄₇

From the above two correlations it can be seen that the relative magnitude of I _p is proportional to the impedance of the neutral circle (Z ₅ + Z ₄₅ ), therefore by measuring the current I _p we can also infer the state of the neutral circle.

If during the intervention (Z5 + Z45) increases and / or (Zj ₃ + Z ₇ + Z ₄₇ ) decreases, the unwanted parasitic hazard current, which by its very nature is not directly measurable, will increase.

The present invention is directed to measuring I _{p and} indicating that the limit is exceeded.

The invention is based on the fact that according to the Node Law the following 4 patients can be prescribed:

If Ι ₇ Ip 0, ie Ip If — If

The non-directly measurable I _p hazard current is determined from the individually measurable If and I _r by difference generation.

The differential current is measured as shown in the embodiment of FIG. The currents of the knife 3 through the active conductor 2 and the neutral electrode 5 through the neutral conductor 6 are excited by a magnetic core 9 made of magnetic material and sensed by means of a measuring sensor coil 10 with thread number N}.

The indicator coil:

Ui = NjA (Nf If-N _r I _r ) where A a is the magnetic conductivity of the ring core 9, N _{f is} the thread number of the active conductor 2 on the ring core 9,

N _{r is} the number of passages of the neutral conductor 6 on the annular core 9.

If we choose Nf = N _r = N then

Uj = N NiA (I _f -I _r ) = K Ip, where N denotes both the Nf and N _r thread numbers and K denotes the aggregation of the expression N Nj A, the voltage proportional to the hazard current I _p can be measured directly at the output, A In this embodiment of the invention, both Nf and Nf are equal to one.

The reliability of the measurement can be increased by automatically reducing the annular core 9 to zero. As a result, the magnetic material properties are out of the factors determining the accuracy of the measurement.

In the embodiment shown in Fig. 4, the voltage Uj is converted to a current If _b, amplified by a transfer admittance 12, and fed to a feedback coil 11, Mft. The feedback current If _b reduces the excitation to zero. At:

N (I _f -If) -N _fb If _b = 0 and I _p = - ~ I _fb .

Thus, the hazard current can be traced back to the measurement of If _b and knowledge of the speed ratios. The measurement accuracy is determined by the accuracy of the current If _b at 0 excitation. In the solution of Fig. 3, the voltage is New, in the embodiment of Fig. 4, If _{b is} capable of transmitting a hazard signal. With our solution, previously uncertain contact states and the amount of current that is unwanted from the patient can be determined continuously, without the least inconvenience to the staff, doctor or patient. Neutral electrode status, cable current3

Its 191,282 tonne is also continuously and more reliable than previous processes.

The annular core 9 can also be formed of two preferably semicircular annular core portions. In this case, detection can be easily performed on existing systems without disrupting the active conductor 2 or the neutral conductor 6.

The invention is not limited to the solutions described in the embodiments, but encompasses all the solutions protected by the claims, in particular the main claim.

Claims (2)

Apparatus for measuring hazard currents in the use of surgical high frequency cutting and coagulating apparatus, wherein one terminal of a high frequency generator is connected via an active conductor to a surgical cutting device, in particular a knife, and the other terminal of a high frequency generator is connected characterized by that The active conductor (2) and the neutral conductor (6) are guided through an opening (9) of a magnetic core and a measuring sensor coil (10) is arranged on the annular rail (9). (02.05.1982). Device according to claim 1, characterized in that the terminals of the measuring sensor coil (10) are connected to a transfer admittance (12) and the terminals of the transfer admittance (12) are connected to a feedback coil (11) arranged on the annular core (9). (02.05.1982.) ¹ 5 3. Device according to claim 1 or 2, characterized in that the ring core is formed összeerősíthetően (9) comprises two, preferably semicircular ring core parts. (9/12/1983). 4 pieces of drawing