DE3621572A1 - Circuit arrangement for operating an RF surgical instrument - Google Patents

Abstract

In comparison with the main patent (Patent Application P 3544460.6) it is intended to avoid interfering influences which may arise due to the supply lead capacities (Ca1, Ca2) of the active electrode (14) and/or of the neutral electrode (18). It is proposed, according to the invention, that this object is achieved in that the ammeter (38 and/or 42) of the monitoring circuit is located on bypass paths in the direct vicinity of the associated electrode (14 and/or 18). These can be accommodated in the handle (13) of the active electrode (14) or in a plug connector (17, 17a) for the neutral electrode (18). <IMAGE>

Description

The invention relates to a circuit arrangement tion for the operation of an electrosurgical unit, the one HF generator contains a connection for the acti ve electrode and another connector for the new central electrode, with a comparator,

• a) where the active and the neutral electrode over one ammeter each to measure the through flowing current is provided with the connector or the further connection is connected,
• b) the ammeter on the output side with a ver are linked, the link of the currents in the sense of a current ratio is seen and that depends on the connection emits link signal,
• c) the link as a comparator Comparator is assigned, which for comparing the Ver link signal with a predetermined limit is seen, and
• d) where the output signal of the comparator as a release besignal is tapped, according to patent ............ (Patent application P 35 44 460.6-, VPA 85 P 8544 DE).

In the mentioned patent .......... it is stated that the earth capacity, the active electrode and its zu own line, and / or the earth capacity, which the new Have central electrode and its lead, too Schwie or even falsify the measurement result in the described monitoring circuit for prevention can lead to "unwanted burns".

It is the task of the present additional invention that at least from one of these two earth capacities reduce resulting difficulties.

The additional invention is based on the consideration that the difficulties can be largely avoided, if the current measurement is near the concerned Electrode.

The above object is thereby ge triggers that the ammeter is in close proximity to the associated electrode is arranged.

With such a construction, with the more advantageous wise both ammeters close to their associated Electrodes are arranged, the currents in unmit close proximity of the patient is measured so that the earth capacities of active electrode including supply line and / or neutral electrode including the supply line is not particularly good weight.

A preferred further development is characterized by that the ammeter for the active electrode in the handle this electrode and / or the ammeter for the new trale electrode in a connector that the neutra le electrode connects to their supply line is.  

Further advantageous embodiments are in the Un marked claims.

The invention is described below with reference to two figures explained in more detail. Show it:

Fig. 1 shows a safety device in which the HF currents of the active and the neutral electrode of an ungrounded HF surgical device are measured and related to each other, according to Fig. 2 of the main patent, and

Fig. 2 a preferred embodiment of a monitoring device with an arrangement of the ammeter in hand and in a connector.

According to Fig. 1 a floating electrosurgical unit 2 includes egg NEN RF generator 3 ', the processing by an RF transformer scarf and inner or replacement resistors R 1, R 2 is Siert symboli. Earth or mass is denoted by 7 . To a non-grounded HF connection 8 , a surgical handle (shown schematically in FIG. 2) is connected via a connecting line 9 , which is equipped with a manually operated switch for switching on an HF working current I _A. This handle is conductively connected to an active electrode 14 which is pressed onto the blood vessel to be breast-fed in patient body 16 during coagulation. A one-piece (undivided) neutral electrode 18 is attached to the patient's body 16 in a conventional manner. In the present case, this is drawn in at some distance in order to illustrate a patient capacity C _p between patient 16 and neutral electrode 18 . From the neutra len electrode 18 leads a connecting line 19 to the other RF connector 20 of the HF surgical device 2nd This RF connector 20 is also not connected to ground 7 .

The capacities essential for the current distribution are shown in FIG. 1. The main current path goes from the HF connection 8 via the line 9 to the active electrode 14 through the patient 16 and through the capacitance C _p to the neutral electrode 18 and via the line 19 to the HF connection 20 of the HF surgical device and back. All other capacitances C _a , C _{a 1} , C _{a 2} , C _{p 1} and C _i (replacement capacitance for C _{i 1} and C _{i 2} ) shown in FIG. 1 lead to bypass paths. A secondary current path for the HF current thus goes through the earth capacitance C _{a 1} , which have the feed line 9 and the handle, which lead to the active electrode 14 . The measures described below prevent this bypass flow path from appearing in _a disruptive manner via the capacitance C _{a 1} . Another bypass path leads via the earth capacitance C _{a 2} , which the neutral electrode 18 and its feed line 19 have. The measures described below largely avoid the difficulties caused by this capacitance C _{a 2} .

By means of a monitoring circuit or safety device described in the following, the current path from this active electrode 14 to the patient is passed through an HF measuring or working current, which is preferably given in pulsed form and which flows as current I _A via the active electrode 14 16 and the neutral electrode 18 back to the HF surgical device 2 checked. This can be done before the actual coagulation process. Only when the measuring current returns completely or within a specified tolerance, which is taken as the current I _N flowing through the neutral electrode 18 , that is to say when the side currents to be expected are unharmfully small, is a release signal g , h for releasing the actual one HF working current released for surgical intervention. Monitoring can also take place during the coagulation process, because the measuring method described here operates within certain limits regardless of the level.

According to FIG. 1, the monitoring circuit comprises a first current sensor or current transformer 38 for the current I _A; the measured value I _A determined is fed to one input of a comparison circuit 40 . Furthermore, the monitoring circuit comprises a second current sensor or current converter 42 , which measures the current I _N via the neutral electrode 18 . The measured value I _{N recorded here} is fed to the other input of the comparison circuit 40 . It is noteworthy that both ammeters 38 and 42 are arranged in the immediate vicinity of the associated electrodes 14 and 18 in this embodiment. This arrangement of the ammeters 38, 42 in the vicinity of the electrodes 14 and 18 has the advantage that the lead capacitances C _{a 1} and C _{a 2} or the HF currents which are derived via these lead capacitances C _{a 1} and C _{a 2} not be measured and can thus falsify the measurement result.

The enable signals g and / or h are emitted at the outputs of the comparison circuit 40 , depending on the comparison of the two currents I _A and I _N. In the comparison circuit 40 , the currents I _A , I _N are set to one another in the ratio I _A / I _N.

It is preferably carried out in such a way that the current I _{A is determined} using a current transformer 38 and a miniaturized downstream electronic circuit which are housed directly in the handle of the active electrode 14 . Likewise, the feed line 19 to the neutral electrode 18 is preferably provided in the immediate vicinity of the neutral electrode 18 itself with a plug-in connector (coupling) in which the current converter 42 is also accommodated with a downstream miniaturized electronics.

In FIG. 2, a preferred practical solution is shown for the monitoring circuit. In particular, details of a preferred embodiment of the logic circuit 40 are shown. The currents I _A and I _N are in turn fed to the current meters 38 and 42 .

Each ammeter 38 , 42 is followed by a member 58 or 60 for forming the effective value of the current I _A or I _N. The outputs of the two components 58 , 60 are connected to a link 62 . The Committee is to circuitry linking the Ef of the currents I _A, I _N fektivwerte provided and there is a dependent of the shortcut link signal v from. The logic element 62 is in particular designed as a ratio generator, which forms a logic signal v loga rithmically dependent on the ratio I _A / I _{N of} the two currents. For this purpose, each of the members 58 , 60 is followed by a logarithmic member 64 or 66 . The logarithmic rms values of the currents I _A , I _N are subtracted from one another. This is done by means of an inverting element 68 , which is connected downstream of the logarithmic element 64 , and by means of an addition element 70 , to which both the output signal of the logarithmic element 66 and the output signal of the inverting element 68 are fed. The output signal of the adder 70 is a linking signal u . It represents the difference between two logarithmic rms values and can assume positive or negative polarity. The Bauglie the 68 , 70 are to be considered together as a subtractor or differentiator. Both the positive and the negative linking signal u are further processed. For this purpose, a rectifier 74 is connected to the output of the adder 70 . Its output signal is the link signal v . The further processing happens as described in the main patent ........... (patent application P 35 44 460.6).

From Fig. 2 it is clear that the electro-African circuit arrangement shown is divided into three parts:

The first part contains the current transformer 38 , the effective value generator 58 and the logarithmic element 64 . This first part is preferably housed in the handle 13 of the active electrode 14 . The handle 13 is shown here schematically as a dashed block.

The second part contains the current transformer 42 , the effective value generator 60 and the logarithmic element 66 . These members 42 , 60 , 66 are preferably housed in a plug connector or a coupling 17 , the coupling elements are schematically designated 17 a .

The third part includes the remaining surveillance scarf tung. The rest of the monitoring circuit is as in Main patent described in the high frequency generating Ge advises himself accommodated.

The first part and the second part are supplied by two conventional power supplies (not shown) which are assigned to the two connections 8 and 20 and are used there for triggering (push buttons in the handle) and neutral monitoring. The leads 9 , 19 to the active electrode 14 and to the neutral electrode 18 should therefore consist of two wires each. By overlaying the measuring currents from the first part and the second part or using an additional wire each, the values I _A and I _N measured on site can be transmitted to the HF-generating device 2 .

From Fig. 2 it can also be seen that as a new element for connection between the first part and the third part, a potential separator 94 is used for the measured value I _A. This potential isolator 94 can, for example, be designed as an isolation amplifier. Correspondingly, a potential separator 96 for the measured value I _N is arranged for the connection between the second part and the third part. This potential isolator 96 can also be designed in particular as an isolating amplifier. Under certain circumstances, finished modules available on the market can be used for both isolating amplifiers 94 , 96 . The potential isolators 94 , 96 are advantageously accommodated in the HF churging device 2 .

Finally, it should be noted once again that the arrangement of the ammeters 38 and / or 42 in the immediate vicinity of the associated electrode 14 and / or. 18 has the advantage that the interference from the capacitances C _{a 1} and C _{a 2 become} very small or disappear completely. These measures can also be used with the same effectiveness for a single-sided HF surgical device.

Claims (9)

1. Circuit arrangement for operating an HF surgery device ( 2 ) which contains an HF generator ( 3 ') which has a connection ( 8 ) for the active electrode ( 14 ) and a further connection ( 20 ) for the neutral electrode ( 18 ), with a comparison element ( 76 ),

• a) wherein the active and the neutral electrode ( 14 , 18 ) via a respective ammeter ( 38 , 42 ), which is provided for measuring the current flowing through ( I _A , I _N ), with the connection ( 8 ) and the other Connection ( 20 ) is connected,
• b) the ammeters ( 38 , 42 ) are connected on the output side to a logic element ( 62 ) which is provided for linking the currents ( I _A , I _N ) in the sense of a current ratio and which has a logic signal which is dependent on the logic ( v ) delivers,
• c) a comparator ( 76 ) is assigned to the logic element ( 62 ) as a comparison element, which is provided for comparing the logic signal ( v ) with a predetermined limit value ( v ), and
• d) the output signal of the comparator ( 76 ) being tapped as an enable signal ( g , h ),

according to patent ............. (patent application P 35 44 460.6-, VPA 85 P 8544 DE), characterized in that the ammeter ( 38 and / or 42 ) in the immediate vicinity of the associated electrode ( 14 and / or 18 ) is arranged. 2. Circuit arrangement according to claim 1, characterized in that the ammeter ( 38 ) in the handle ( 13 ) of the active electrode ( 14 ) is brought under. 3. Circuit arrangement according to claim 1 or 2, characterized in that the ammeter ( 42 ) in a connector ( 17 , 17 a ) is housed, which is connected in the immediate vicinity of the neutral electrode ( 18 ) to this. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the ammeter ( 38 ; 42 ) has a miniaturized electronic circuit ( 58 , 64 ; 60 , 66 ) connected downstream, which if just in the immediate vicinity of the associated electrode ( 14 and / or 18 ) is arranged. 5. A circuit arrangement according to claim 2 and 4, characterized in that a current transformer is provided as the ammeter ( 38 ), which has a downstream effective value generator ( 58 ) and a downstream logarithmic element ( 64 ) in the handle ( 13 ) of the active electrode ( 14th ) is housed. 6. Circuit arrangement according to claim 3 and 4 or according to claim 3, 4 and 5, characterized in that a current transformer is provided as the ammeter ( 42 ), which with a downstream effective value generator ( 60 ) and a downstream logarithmic element ( 66 ) in the connector ( 17 , 17 a ) for the neutral electrode ( 18 ). 7. Circuit arrangement according to claim 5 or 6, characterized in that the Lo garithmierlied ( 64 , 66 ) is followed by a subtraction member ( 68 , 70 ) which is housed in the housing of the rest of the HF surgical device ( 2 ). 8. Circuit arrangement according to one of claims 4 to 7, characterized in that the electronic circuit ( 58 , 64 ; 60 , 66 ) as a potential isolator ner ( 94 ; 96 ) is followed by an isolation amplifier.