DE3610393A1 - Method and evaluation component for determining high-frequency (radio-frequency) fault currents - Google Patents

Abstract

The invention relates to a method for determining an uncontrolled current (fault current) when feeding high-frequency energy to a body which is mounted on a frame, for example a table, which is earthed via an earthing line, in particular for the purpose of high-frequency surgery, according to which the fault current is measured by means of an evaluation component and, when a basic value is exceeded, a fault current signal is output.

Description

The invention relates to a device for

Detection of an uncontrolled current (fault current) when supplying high frequency energy to a body, e.g. a patient, from the output terminals of a high frequency generator via a first and via one connected to earth second feed line and via connected to the feed line with the body electrodes in contact with the body on a storage rack, e.g. a table, is stored, in particular for the purpose of HF surgery, and wherein the Residual current by means of a switched on in a connection leading to earth Converter to which an evaluation part is connected, measured and when exceeded of a basic value, a fault current signal is emitted, by means of which a warning device can be operated.

Such devices are disclosed in U.S. Patents 4,200,105 and 4,231,372 known.

Uncontrolled currents, commonly referred to as fault currents can lead to disruptions in operation and even to life-threatening situations for people. It is therefore common practice to use a fault current switch in mains operated devices upstream. Correctly proceeding currents flow to one on a ladder electrical device or the like. there and back on the return conductor.

Both currents flow through the fault current switch in such a way that that with proper current flow, the effect of the currents on the fault protection switch picks up and this is not actuated. However, if there is a part in the device circuit of the current, e.g. as a result of an insulation fault or via one with the power supply person coming into contact, after earth is derived and so not on the normal Path flows back, the residual current circuit breaker detects a current difference and disconnects from the network.

For devices that supply high-frequency energy and the residual current switch is switched on in the RF power lines, because of the high frequencies and the possibly occurring phase shifts, if necessary the correct one Impaired effect and function cannot be guaranteed.

Strong high-frequency currents, voltages and powers are used e.g. in high frequency surgery.

A needle-shaped electrode, for example, generates a high frequency Current is delivered into the tissue of a patient, the one entering from the electrode Electricity creates limited tissue destruction while reducing bleeding.

The high frequency can be in the form of undamped, preferably sinusoidal, There are vibrations. There are also known spark generators that, at short intervals, thus creating impulses, vibrations of decaying amplitude.

The frequency is usually in the range above 500 kHz 1.7 MHz.

The supplied high-frequency energy enters the patient's body and there is a large cross-section of the wire, so that none inside the body annoying heating occurs; the heating is only maintained at the needle, in the vicinity of which the current is narrowed to a minimal cross-section. The draining one Electricity is drawn from the body at a neutral electrode, which has a large area is attached in a suitable place, e.g. around the thigh. With a tight fit Neutral electrode occurs no noticeable warming up here either and the current can be sent to the generator via a cable connected to the neutral electrode be returned. Fig. 1 shows such a known arrangement.

A patient 2 is positioned on an operating table 1.

The operating table 1 is provided with a metal plate 3, and between This plate 3 and the patient 2 is an intermediate layer 4, for example made of absorbent Material, appropriate.

The table 1 is supported by a stand 5a, 5b, which is usually according to the prior art consists of one piece. This stand is shown below commonly referred to as a foot. The foot 5a, 5b is connected to a base plate 6 and placed on the floor 7. The base plate 6 is connected via an earth conductor 8 connected to earth; since the parts 1, 3, 5a and 5b are conductively connected to the base plate 6 these parts are also earthed.

This earth is a general earth, which is shown in Fig. 1 below as horizontal continuous dashed line 9 is shown. With this grounding are all neutral parts connected around the operating table. In the floor of the operating room can further be embedded metallic strips 9a, which are also connected to the ground 9 are connected via earth conductor 9b. This ensures that there is also on the floor cannot develop any disruptive potentials. Put the strips 9a thus one Equipotential bonding. The grounding 9 is known in Way connected to at least one earth point in the building and / or the subsoil.

An HF generator 10 is shown above the patient an output winding 11 high frequency currents of suitable strength, voltage and shape that can be removed from terminals 12 and 13. The generator is over a cable 10a connected to the AC network; this cable also includes one Protective earth conductor lOb, which optionally via a connecting conductor 10c to the Earth conductor 21 or otherwise connected to the general earth 9.

The terminal 12 is connected to the, e.g. needle-shaped, active electrode via a cable 14 15 connected, with which the surgeon performs the necessary interventions.

The terminal 13 is connected to the neutral electrode 17 via a cable 16. The high-frequency current supplied via the needle 15 enters the patient's body 2 and flows via a current path indicated by a dashed line 18 to the neutral electrode 17 and via the conductor 16 to the output terminal 13 of the generator 10 back. The current flowing back in the body is of course not limited to a specific one Area set around line 18.

The rest of the body can also have more or less high line resistances of part of the over the active electrode 15 supplied high frequency Current flowing through it.

In the circuit described so far, in which the generator output terminals 12 and 13 are only connected to the active electrode 15 and to the neutral electrode 17, respectively are, the current from the active electrode 15 could roughly correspond to the dash-dotted line current path 19 shown flow downward through the body of the patient 2; he finds very little resistance. When the liner 4 is dry is, a capacitor becomes between the body of the patient 2 and the metal plate 3 formed, via which the high-frequency current can reach the plate 4. Also between there is a capacitive transition between the neutral electrode 16 and the plate 4, and so on can the current from the electrode 15 through the body and the capacity formed through to plate 4 from this back via the capacitance formed to the neutral electrode 17 flow, so that a further current path is formed parallel to the current path 18 provided will. If there is an accumulation of fluid in the intermediate layer 14 under the patient 2 at 20 has formed, a relatively low-resistance current bridge to the plate 4 is formed.

As a result, the fault current via the current path 19 can be significantly stronger will. If the neutral electrode 17 is loose, the resistance increases over the current path 18, and the current share via the current path 19 is correspondingly greater. In the vicinity of the transition from the current path 19 via the conductive area 20 to Plate 4 can be hence a clear concentration of the current, result in increased warming and possibly combustion.

The high-frequency generator 10 is usually via a conductor 21 is connected to ground, and terminal 13 of output winding 11 is also connected via a Connection 22 to the ground terminal 23 of the generator 10 and thus via the line 21 connected to earth. The metal plate 3 is over the foot 5a, 5b, the Base plate 6 and the earth conductor 8 grounded. Currents over the dash-dotted line Current path 19 then flow to plate 4, via earth conductor 8 to earth and over conductors 21 and 22 back to the end of the output winding connected to terminal 13 11. There is thus a fault current on the line 21, 22, and the current through the conductor 16 is reduced accordingly.

It can also happen that the fingertips 25 - outside of the intermediate layer 4 - touch the metal plate 3 directly.

It is then possible that from the active electrode 15 through the body of the patient, e.g. corresponding to the dotted line 26, a partial flow via fingertips 25 to earth and via lines 21 and 22 to the generator 10 flows back, which then does not flow through line 16.

The contact area of the fingertips 25 with the plate 24 can be small be, so that there occurs a high current density and strong heating, the to burns can lead. The line 26 shown corresponds to the current flow when the arm is close to the body.

But even if this is not the case and the mentioned fault current another way, e.g. over the shoulder 27 into the arm and to the fingertips 25, the same errors can occur; because the way through the arm shows such a large cross-section that the conductivity is high enough to the to cause mentioned current division.

Another electrical treatment device, such as an electrocardiograph, can also be used 28, which is grounded on the one hand by a terminal 29 via a line 30 is and of which a measuring terminal 31, which via a line 32 with an electrode 33 is connected to the patient, also via a connecting line 34 in the device 28 is connected to the ground terminal 29. Then the electrode 33 is also located to earth, so that from the active electrode 15 over the lines and double Line 35 shown dots shows a fault current from the active electrode 15 via the Lines 32, 34, 30 to earth and on via lines 21 and 22 to the output terminal 13 can train. Each of these fault currents can possibly occur at parts of the body, at which there is a narrowing of the current and thus a stronger development of heat, lead to malfunctions or injuries.

In the known arrangements according to US-PS 4,200,105 and 4,231,372 the fault current is drawn from the line that is used to supply the HF energy is used on the patient electrode. This results in an undesirable coupling of useful current and residual current, which is an exact function of the residual current determination can affect.

The invention is based on the problem of the high-frequency fault current to record and measure independently of the useful current in order to avoid disturbances, in particular burns and the like of a patient with greater certainty.

The object is achieved according to the invention in that the bearing frame connected to earth and placed the transducer in the earth connection of the storage rack is.

In this way, the measurement of the fault current from the utility circuit, in which strong currents can flow, separated, so that a disturbing influence fault current measurement is avoided.

The HF energy practically always creates a certain basic value of the Caused fault current, which is in particular due to capacitance. This core value is so small that it causes disturbances, especially injuries to a patient, are not to be feared; this base value is, for example, well below 1 mA. Undesirable effects are only to be expected when the current is much higher Values, e.g. between 1 and 10 mA, are reached. The limit up to which a fault current is harmless, depending on the apparatus in question, the vibrations used and energies are determined and established in practice.

If this limit of the fault current is exceeded, after the Invention triggered a signal. This signal is intended to indicate the risk of doing so if necessary, remedial action can be taken. An immediate shutdown of the energy supply, as is usual with a residual current circuit breaker in the mains supply line is, is usually not desired in the present case; because then work with the high-frequency energy would be interrupted immediately, and e.g. during a surgical procedure, complications from an imperfect operation be evoked.

In a preferred embodiment of the invention, the HF energy from the output terminals of a high frequency generator (HF generator) in contact with the body via a first and a second feed line standing electrodes are supplied, and the fault current is removed by means of a converter a ground line scanned and fed to the evaluation part. The first and the second Feed lines are with the active electrode or with the neutral electrode tied together. The converter forms a transformer, whose primary side from the fault current is fed. On the secondary side, the transformed current can be sent to the evaluation part be fed; then the transformer essentially acts as a voltage converter. It is The transducer can preferably be connected to the earth line of the patient support frame be inserted. This frame can take the form of one or more feet or legs have, as is usual with furniture, including medical furniture, of various types is.

According to one embodiment of the invention, in the evaluation part the fault current signal supplied by the converter via an amplifier of a threshold value device supplied, and when a base value of the measured fault current is exceeded a fault current signal is formed, by means of which a warning device is actuated. The warning device can be optical and / or acoustic and for example a lamp or a tone generator in connection with a loudspeaker contain. Switching on one or the other warning device can, if necessary be made dependent on the strength of the measured fault current.

According to a particular embodiment of the invention, the Body, e.g. of a patient, on a sitting-standing or lying furniture or the like. formed frame, e.g.

on an operating table, and at least one on the floor The upright foot of the piece of furniture is equipped with an increased RF resistance Break provided with the upper part of the foot above the break over at least one line with earth, possibly with the earthed lower part of the foot, is connected and the fault current or fault current flowing through this line

Residual current component is measured by means of the evaluation part. the Interruption can be designed to be practically completely insulating, but it can also lead a noticeable part of the total fault current in such a way that only one Fault current part is fed to the evaluation part via the converter.

According to a preferred embodiment, the increased RF resistance achieved in that between the upper and the lower part of the foot or one Leg or another part of the frame arranged an insulating plate is, which carries a conductive layer on its upper and lower side, the is in communication with the metal parts of the upper and lower foot parts; these layers are connected to the primary winding of the transducer in such a way that at least a part of the fault current flowing from the upper to the lower foot part to the evaluation part is fed.

The upper and lower parts can be attached to one another by connecting elements, e.g. screws, which are used for high-frequency vibrations Have resistance compared to the resistance between the conductive layers has a noticeable value via the converter. The fasteners will so no complete bridging for high frequency vibrations; e.g. can a current division in the ratio 2: 1 between the connecting elements and the converter input can be achieved. For this purpose, the surface of the connecting elements is preferably e.g. profiled in a spiral - like a normal screw. Because high frequency is preferably conducted on the surface of a metallic body, e.g. in the case of an iron screw, the connecting elements achieve the high frequency derive only imperfectly. On the other hand, these connecting elements conduct at mains frequency with its entire cross-section. Any strong line-frequency current is thus discharged unhindered to earth, with damage to the converter input respectively. of the evaluation part is not to be feared.

The primary winding of the converter into the earth line is useful switched on and a secondary winding connected to the evaluation part. Through this the input of the transducer can be kept very low-resistance, so that the grounding Function is not impaired. On the other hand, through transformation to the secondary winding a fault current signal of a suitable size for the control of the evaluation part can be obtained.

A particularly simple structure results from an arrangement in which the converter is combined with the evaluation part. Then there are only the signal transmitters, preferably via a flexible line, to be connected and at a suitable location set up in the operating room. The evaluation part can, if necessary, be somewhat separated from the transducer, to be attached to the upper or lower foot part, resulting in a stable and space-saving structure.

The evaluation part can also be combined with the high-frequency generator so that if necessary the feed energy is supplied by this. There a Residual current signal is only of interest when the HF generator is in operation is, the feed of the evaluation part is ensured in these time intervals.

The arrangement can also be made so that the evaluation -Part is arranged separately from the converter. Because the output of the converter has a higher impedance are impairments due to a longer connection line to the evaluation part not to fear. The evaluation part can then be placed in a suitable place, e.g. at Anesthetists will be ordered. This can be done with a suitable design of the evaluation part then also monitor different fault current signals.

The converter itself can then be on the upper or lower part of the table base arranged and connected to the evaluation part via a flexible line.

For the converter, it is advisable to choose the dimensioning so that it has a low input impedance and that its output at high frequency a supplies sufficient control variable for the evaluation part. The primary winding can consist of a single turn or a part thereof. Such a single one The input turn can be designed in such a way that there is a mains alternating current flowing through it transmits without a noticeable drop in voltage.

The converter expediently points to the ones supplied by the HF generator Vibrations resonance. Its transmission rate is then also great for high frequency with low input resistance in the earth line. E.g. the input turn for high frequency have a series resonance and / or the secondary winding can Show parallel resonance behavior. Thus a converter according to the invention even Can be used with different high frequency generators, can resonance be adjustable.

The resonance can also be lower than the frequency of the vibrations of the HF generator. Then the often sharp resonance peak lies outside the transmission range, and the amplitude of the transmitted fault current signal is not so much of any eventuality Changes in the frequency of the HF oscillations are dependent.

The converter is expediently designed for a basic value of the high-frequency fault current in the milliampere range, e.g. on the order of 1 to 10 mA, and it is for one Fault current suitable, which is at least twenty times as large as the basic value, in particular can be up to 500 mA or more.

According to an expedient development, the converter is about a for High-frequency permeable filter on the earth line and / or on the evaluation part connected. The converter and / or parts of the input circuit of the evaluation part can be included in the filter. A simple filter can be coupled through a capacitor are formed. This ensures that line-frequency short-circuit currents do not lead to Evaluation part can be transferred. The earth line into which the converter is switched should be bridged for large currents, e.g. 5A to 20A, to avoid a network short circuit derive.

In the case of an evaluation part for a method or an arrangement according to According to the invention, the power is to be expediently carried out by a battery, so that high Fuse for reporting a fault current is achieved. The Supplied by an accumulator, which is preferably permanent or intermittent, e.g. at night, is charged by means of a charging circuit.

The evaluation part can expediently supply an operating voltage in the event of a warning to a signal transmitter, so simply switch it on. So can act as a signaler an optical device, e.g. a lamp, or an acoustic device, E.g. a loudspeaker or headphones controlled by a sound generator. The speaker is permanently connected to the tone generator, possibly via an amplifier, and the signal is emitted as soon as the operating voltage is fed to the tone generator will.

The evaluation part can depending on the type and / or size of the fault current provide different warning signals. So can with a very weak fault current only a visual warning can be given, while in the event of a higher fault current an acoustic signal is triggered and reaches the surgeon immediately. at a very strong fault current can be emitted by the evaluation part by means of the Fault current signal, the HF generator can also be switched off.

The signal transmitter is activated by the evaluation part when an appears above switch on the warning signal transmitter immediately, but only if the fault current that has occurred disappears, e.g. by 5 to 10 seconds delayed, switch off again. This can also be the case if the limit is exceeded briefly of the basic value, a warning signal can be given over a longer period of time, and so do the operating personnel be reliably made aware.

As it is for the safety of a patient on the reliability of the Fault current signal evaluation is very important, can in the evaluation part, especially in Battery or accumulator operation, expediently a supply voltage tester included which is a warning signal when the supply voltage falls below a limit value gives away.

This warning signal can be appropriate in pitch and / or differ in the interval duration from the fault current warning signal. E.g. can through the battery tester the tone generator at intervals of e.g. 5 seconds, twice Switched on for 1/2 second.

The invention is illustrated below with reference to the drawing, for example explained in more detail. It shows F i g. 1 an operating table with the device parts and Circuit connections according to the invention, FIG. 2 a contact plate with the transducer and F i g. 3 a circuit for signal processing.

1, a known method with the associated Device parts described, it being assumed that the foot 5a, 5b of the operating table 1 is formed continuously from top to bottom, preferably in one piece. The fault current from table 1 to base plate 6 and via line 8 to the ground 9 flows through the foot 5a, 5b.

In order to be able to measure the fault current according to the invention, the foot is interrupted between its upper part 5a and its lower part 5b. The lower End of the upper part 5a and the upper end of the lower part 5b go into flange-like Widenings 36 over, which form an approximately square area (see Fig. 2, left Part).

At the corners of these squares there are holes through which the upper and lower flanges 36 and 37 are fastened together with screws 38 can be.

An insulating plate 39 is attached between the flanges 36 and 37, which has a conductive layer on its upper and lower side. These Conductive layers 40 and 41 are connected via lines, e.g. insulated wires, 42 and 41 respectively. 43 connected to the ends of the primary winding 44 of a converter 45. Its secondary winding 46 is connected to lines 47 and 48, one of which can be grounded Input 49 of an evaluation part 50 is connected.

The conductive layers 40 and 41 are in metallic contact with the flanges 36 or 37. A high frequency flowing from the operating table 1 to earth Fault current can thus flow through the primary winding 44 of the transformer 45. If the screws 38 are inserted in an isolated manner, almost all of the fault current will be flow through the converter 45 and a correspondingly large fault current signal to the Supply input 49 of evaluation part 50.

In practice, however, the screws 38 can be used uninsulated so that they establish a conductive connection between the two flanges. The areal contact between the layers 40 and 41 of the plate 39 and the Flange parts 36 and 37, however, have a large expansion, while the screws overall only have a small cross-section. Already from the cross-section or

the surface can therefore conduct the current via the layers 40 or 41 be favored. These layers are also made of a highly conductive material, e.g. Copper and / or silver and they are made by copper lines 42 and 43 connected to a copper wire winding 44. In addition, the screws 38 are made of iron and have a helically profiled surface, which is their conductivity for high frequency decreased. However, there is high frequency between the layers 40 and 41 also have a shunt impedance across that between layers 40 and 41 with the insulating material 39 formed capacitance. Overall, it has been shown that without difficulty the training so can be hit that a considerable part, e.g. two thirds, of the total through the foot 5a, 5b fault current flowing through primary winding 44 of converter 45; included this winding can be formed in that the lines 42,43 around the core of the transducer 45 are guided around as a single turn.

Fig. 1 is based on an embodiment that contains the essential parts can be seen roughly schematically. The practical constructive execution can be of this differ. In particular, the interruption with the insulating layer 39 can be direct be arranged below the operating table 1.

This is particularly recommended when this operating table is designed to be removable in order to be able to easily transport the patient.

Fig. 2 shows a plan view of the insulating plate 39 with the above lying conductive layer 40, which merges into a terminal lug 51. They don't The visible lower layer merges into a terminal lug 52. Inside the plate 39 is by a dashed line 53 the outer contour of the cylindrical the lower foot part on which the square (lower) flange plate 37 is attached. The insulating plate 39 with the conductive layers 40 and 41 is recessed at the corners in the area of the screw holes of the flange plates 36 and 37, which makes the assembly easier.

In Fig. 2, the converter 45 is shown in section on the right.

It consists of an annular core 55 with a rectangular core, e.g. made of high frequency ferrite. Around this annular core is a secondary winding 46 attached, the winding ends of which to the lines 47 and 48 to the evaluation part 50 are connected. The lines 42 and 43 form a closed loop, so that the primary winding 44 of the transducer 45 through a single, through the interior of the annular core 55 passing through conductor is formed. The entrance of the Converter 45 thus has a very low impedance, while through a high one Transformation ratio to the secondary winding 46 ensures that in the evaluation part 50 a sufficient input voltage is supplied.

Fig. 3 shows schematically the circuit arrangement with which from the a warning signal is generated.

The conductive layers 40 and 41, on both sides of the insulating Plate 39 are arranged (see. Fig.l), are via terminals 56 and 57 to the input winding 44 of the converter 45 is connected. The secondary winding 46 is grounded on the one hand connected and on the other hand via a high-frequency diode 58 to a load resistor 59 switched on.

When a fault current signal occurs, it flows through the Primary winding 44, and a voltage occurs across the secondary winding 46, which is generated by the diode 58 is rectified and is available at resistor 59. This tension can consist of half waves of high frequency oscillation; possibly by a the resistor 59 connected in parallel capacitor 60 performed a smoothing will. The secondary winding 46 is a capacitance 61 in parallel, the substantially the resonance behavior of the transducer 45 is determined. The capacity 61 can predominantly be determined by the winding capacities and possibly by a connected one Capacitor can be enlarged.

The rectified fault current signal appears at a terminal 62 and is fed to an input of a comparison stage (comparator) 63. Another The input of the comparison stage 63 is a comparison voltage from a voltage generator 64 fed. The comparison stage works in such a way that it only then has an output signal delivers when the voltage appearing at terminal 62 is greater than that of the Comparison voltage supplied to stage 64. The output signal of stage 63 is over a switch-off delay stage 65 is fed to the signal generator stage 66.

A tone generator 67 is contained in this. When the input signal occurs for the stage 66, the vibrations generated by the tone generator 67 amplified and fed from the output of stage 66 to a loudspeaker 50b, see above that the warning tone can be heard. The activation of stage 66 by the from stage 63 supplied signal can be done in a simple manner that the supply voltage for the tone generator and / or the amplifier is made effective.

This means that if the base value of the fault current is exceeded briefly not only a short warning tone occurs, is between the output of the comparison stage 63 and the input of the signal generator stage 66, a delay stage 65 is switched on. This forwards a signal fed to its input directly to stage 66; but if the signal disappears again, it becomes a certain one from stage 65 Time, e.g. a few seconds, recorded so that the warning tone is not overheard. The same also applies if next to the loudspeaker 50b or in its place a visual indicator, e.g., a lamp, 50a (see Fig. 1) from the output of the signal generator 66 is controlled. The circuit described so far is powered by a battery 69 fed whose minus pole is connected to earth and whose plus pole is connected to a feed line 70 is connected, with which the individual stages 63, 64, 65 and 66 are also connected are. To monitor the battery voltage, a battery tester 71 is between of line 70 and ground switched on. When the battery voltage is a certain If it falls below the limit value, the battery tester 71 sends a control signal to the stage 66 so that the speaker 50b sounds. To be clear Distinction to warn of the fault current warning signal, the battery warning signal can be pulsed, thus consisting of short intervals and / or for the battery warning a different pitch can be selected by tuning the tone generator 67 differently or another, not shown, tone generator is used.

The invention is not limited to the above scope of the method according to the invention limited. Rather, there is also another preferred one Area of application in the monitoring of the neutral electrode of EKG devices as well in the monitoring of examinations that work with live body contact units and therapy devices.

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Claims (24)

Claims 1. Device for detecting an uncontrolled Current (fault current) when supplying high-frequency energy to a body, e.g. of a patient, from the output terminals of a high frequency generator via a first and a second feed line connected to earth and via to the Electrodes connected to the feed line and in contact with the body, wherein the body is supported on a storage rack, e.g. a table, in particular for the purpose of HF surgery, and wherein the fault current by means of an in one after Earth-carrying connection of switched-on converter to which an evaluation part is connected is measured and emitted a fault current signal when a basic value is exceeded is, by means of which a warning device can be actuated, characterized in that, that the bearing frame (1,5a, 5b) is connected to earth and the converter (45) is connected to earth of the storage frame (1,5a, 5b) is arranged. 2. Apparatus according to claim 1, characterized in that the body (2), e.g. of a patient, on a piece of furniture as sitting, standing or lying furniture or the like. formed frame, e.g. an operating table (1,5a, 5b, 6) is and at least one on the floor (7) standing foot (5a, 5b) of the furniture one, An interruption exhibiting an increased HF resistance, possibly insulating (39), the upper part (5a) of the foot having at least one line (42,43,8) is connected to earth (9) and the fault current flowing through this line is measured by means of the evaluation part (50). 3. Apparatus according to claim 2, characterized in that between an insulating plate (39) is arranged in the upper and lower parts (5a, 5b) of the foot which has a conductive layer (40; 41) on its upper and lower side. and that these layers are connected to the primary winding of the transducer (45) are such that at least part of the flowing from the upper to the lower foot part Fault current is fed to the evaluation part (50). 4. Apparatus according to claim 3, characterized in that the upper and the lower foot part (5a, 5b) are attached to one another by connecting elements, e.g. screws (38), which have a resistance for high-frequency vibrations, the in comparison to the resistance between the conductive layers (40,41) has a noticeable value via the converter (45). 5. Apparatus according to claim 3 or 4, characterized in that the surface of the connecting elements (38) is profiled, e.g. 6. Device according to one of the preceding claims, characterized in that that the primary winding (44) of the converter connected to the ground line and a Secondary winding is connected to the evaluation part (50). 7. converter for a device according to one of the preceding claims, characterized in that the transducer (45) has a low input impedance and that its output at high frequency is a sufficient control variable for the evaluation part (50) returns. 8. Converter according to claim 7, characterized in that it is for the from the HF generator part (10) supplied vibrations has resonance and that the Resonance is adjustable. 9. Converter according to claim 7 or 8, characterized in that the Resonance is lower than the frequency of the oscillations of the HF generator (10). 10. Converter according to one of claims 7 to 9, characterized in that that it is designed for a basic value of the high-frequency fault current in the milliampere range, e.g. in the size of 1 to 10 mA. 11. Converter according to one of claims 7 to 10, characterized in that that it is designed for a fault current which is at least 20 times as large as the basic value, in particular up to 500 mA or more. 12. Converter according to one of claims 7 to 11, characterized in that that it is connected to the evaluation part (50) via a filter that is permeable to high frequencies connected. 13. Converter according to claim 12, characterized in that the converter and / or parts of the input circuit of the evaluation part (50) included in the filter is / are. 14. Converter according to claim 12 or 13, characterized in that the converter (45) exercises a capacitor Coupling to the evaluation part (50) is connected. 15. Converter according to one of claims 7 to 14, characterized in that that its input is bridged for large currents, e.g. 5 A to 20 A. 16. Evaluation part for a device according to one of the preceding Claims, characterized in that the power is supplied by a battery (69). 17. Evaluation part 1 according to claim 16, characterized in that the The measuring amplifier is fed by an accumulator. 18. Evaluation part according to claim 16 or 17, characterized in that that in the event of a warning it supplies an operating voltage to a signal transmitter stage (66). 19. Evaluation part according to claim 18, characterized in that as Signal transmitter (66) an optical device, e.g. a lamp (50a), is used. 20. Evaluation part according to claim 18, characterized in that as Signal transmitter an acoustic device, e.g. one controlled by a tone generator (67) Speakers (50b) or headphones are used. 21. Evaluation part according to one of claims 18 to 20, characterized in that that depending on the type and / or size of the fault current, different signals are supplied will. 22. Evaluation part according to one of claims 18 to 21, characterized in that that in the event of a strong fault current by means of the fault current signal, the HF generator (10) is switched off. 23. Evaluation part according to one of claims 18 to 22, characterized in that that the signal transmitter stage (66) is switched on immediately when a fault current occurs, but only if the fault current that has occurred ceases to exist, e.g. by 5 to 15 seconds, by means of a delay device (65) is switched off with a delay. 24. Evaluation part according to one of claims 18 to 23, characterized in that that it contains a supply voltage tester (7) and when the battery supply voltage (69) falls below a limit value, a warning signal, e.g. via a signal transmitter (66) that differs, e.g. in pitch and / or in the interval duration, from the fault current display signal differs.