EP3004904A1

EP3004904A1 - Method and device for detecting contact faults on an electric machine

Info

Publication number: EP3004904A1
Application number: EP14734715.7A
Authority: EP
Inventors: Thomas Wolbank
Original assignee: Technische Universitaet Wien
Current assignee: Technische Universitaet Wien
Priority date: 2013-05-28
Filing date: 2014-05-27
Publication date: 2016-04-13
Also published as: AT514356B1; WO2014190367A1; AT514356A1

Abstract

The aim of the invention is to detect contact faults on an electric machine (2), which is supplied by a converter (4). This is achieved in that a first (V₁) and (one) second voltage (V₂), which is raised relative to the first voltage, are applied in a chronologically sequential manner using the converter (4), and the corresponding machine currents (i₁, i₂) caused thereby are measured. A value for the resistance (r) is ascertained from the quotient of the difference (Δ_ν) of the two voltages divided by the difference (Δ_i) of the two currents.

Description

Method and device for detecting contact errors on egg ^¬ ner electrical machine

More particularly, this invention relates to the field of inverter powered electric machines, and more particularly to a method and apparatus for detecting contact faults on an electrical machine powered by an inverter.

Between an electrical machine and the inverter driving them are usually conductors, terminals, switches, fuses, breakers and the like. Elements. There are usually numerous metal-metal contacts, which can bring a more or less large electrical resistance with it. It should be noted that in such contacts, the contact surfaces are not flat and continuous, but uneven. Accordingly, only small area areas form the actual contact area. Furthermore, with common metal contacts, e.g. Aluminum, copper or brass, non-conductive oxide films, and good electrical contact can be obtained only where a high contact pressure of the oxide film is interrupted.

Now, if such electrical contacts are exposed to comparatively high currents, as is customary in electrical machines used in industry and for drive systems (cf., for example, US 2010/0060289 A1), then these currents lead in the metal-metal Contact areas to a temperature increase, which leads to degradation processes and to an increase of oxide films. In particular, currents in case of overload or short circuit lead to a high excess temperature and as a result to a substantial increase in resistance.

On the other hand, load changes may result in different mechanical pressures or forces in the area of the contact parts, such as bolts and clamps, wherein thermal expansions of different materials are problematic. For example, if one of the contact materials is twice as high

Coefficient of thermal expansion has, compared to the other material involved in the contact, the pressure increases after the Er- heat the connection area to twice. This leads to deformation of the contact parts and possibly to cracks.

Finally, environmental influences in harsh operating environments are also to be considered, such as moisture, dust, dirt, changes in the ambient temperature, vibrations, external mechanical forces and the like. , which can lead to a comparatively high wear and corrosion of contact parts.

An increasing resistance in the region of a contact results in a reduced efficiency of the connecting parts and thus of the entire system. It should also be noted that the degree of reliability of the electrical connections should not be lower than that of the converter and the machine. Studies have shown (see. RS Colby, "Detection of high-resistance motor connections using symmetrical component analysis and neural networks") that compounds with high Wi resistor ^¬ with among the main reasons for the failure of electrical systems. This is not only the high

Resistors themselves problematic, but also the subsequent failures or faults. For example, increased resistance in one phase of a multi-phase machine leads to voltage unbalance in the stator winding and ultimately to

Defects in the stator winding, which is one of the most common failure reasons.

Accordingly, investigations have already been carried out in order to determine elek fresh compounds with high resistance, but these investigations were generally dealt with netzge ^¬ fed machines. However, these test results are virtually impossible to transfer to converter-fed machines. However, in the article Sang Bin Lee et al. , "A New Strategy for Condition Monitoring of Adjustable Speed Induc tion Machine Drive Systems," IEEE Transactions on Power Electro Nies, Vol. 26, No. 2, February 2011

described in which the inverter is drawn during a standstill of the machine for detecting a resistance imbalance, wherein the phase resistances of Spannungsmessunge be determined. There are - as usual - additional sen- sensors, such as voltage sensors, necessary to increase the cost. In addition, the known investigations were usually confined to the detection of faults already occurred in the electrical circuit, whereas it would be desirable to safely and quickly determine ^{starting ¬} nende errors, such as to avoid serious machine damage.

It would therefore be desirable to have a technique for monitoring electrical machines, namely converter-fed machines, without additional circuit complexity and with the possibility of ^detecting increasing resistance increases in contact areas-even without the usual visual examinations and manual resistance measurements. In this case, for example, in machines in drive systems access to connections of contacts is generally not possible without further ado. On the other hand, however, the monitoring technology should be able to do without dismantling.

It is therefore the object of the invention to propose a method and a device for detecting contact errors on converter-fed electrical machines, wherein already starting contact errors should be able to be reliably detected, and wherein a special expenditure on equipment should be avoided.

A further object of the invention is to detect such contact errors early even in the case of multiphase machines, in particular three-phase machines, in particular if they are also present in only one phase and can assign them to the respective phase, as a result of asymmetries can be reduced or avoided in the phase voltages on the stator windings, so as to prevent as possible a machine failure due to a faulty stator winding.

Accordingly, the invention provides a method for detecting contact errors on an electrical machine, which is fed by a converter, characterized in that with the aid of the inverter temporally successively a first and a second, compared to the first increased voltage applied and thereby caused associated machine currents are measured, and from the quotient of the difference of the two voltages by the difference of the two currents, a value for the resistance is averaged.

The invention further relates to a device for detecting contact errors on an electrical machine fed by a converter, having at least one current sensor for detecting a machine current caused by the converter when a voltage is applied to the machine, characterized by a measuring arrangement connected to the current sensor with inverter voltage detecting means and with a resistance detecting unit for generating voltage by quotient of successively applying two different voltages, the second voltage being increased from the first one and causing two different currents Current difference to determine a machine connection resistance value.

The invention is based on the recognition that in an electrical machine immediately after starting the temperature in contact areas will still be equal to the ambient temperature; An increase in the resistance will tend to be negligible or barely detectable in this starting phase. However, as the current through contact increases, perhaps as a result of a corresponding machine load, the resistance will also increase. Now, if a connection or contact point is faulty, the resistance will rise faster here than in contacts. Such a failure is also referred to as a Hot Contact Point (HCP), and the detection of such HCP faults enables it to respond quickly and avoid impacts and failure.

The present technique is thus based on the measurement of current responses to voltage levels generated by the inverter. An advantage here is that usually in a converter circuit already standard current sensors are provided so that in this regard no additional components (hardware) are required. On the other hand, the set by the inverter to ^¬ respective voltage from the activation of the converter here is known, and then when the resulting current is measured, the resistance in accordance with the Ohm can see 'law to be calculated. However, the scale from one drive to the electric Ma ^¬ machine voltage is affected by a non-ideal behavior of the converter, and it would actually be necessary, in addition, the output voltages of the inverter to capture with its own voltage sensors. However, this would lead to increased costs, since voltage sensors for the control or regulation of the machine systems are not required and therefore are generally not available or are not used.

Usually, the output voltage of the converter is generated by the switching thereof according to the known pulse width modulation (PWM). Apart from the discrete pulses thus obtained, this results in further, inherent phenomena, such as voltage drops, edges in the transitions of the output voltage, switch-off and switch-on times, and dead times of the converter. All of these phenomena affect the resistance determination or estimation due to the distortion of the inverter output voltage. These effects should therefore be eliminated or at least reduced without requiring a separate voltage measurement in order to achieve the most accurate possible resistance determination.

This is achieved in the present technique by the aforementioned quotient voltage difference by current difference, as will be explained in more detail below, wherein the vorer ^{¬ mentioned} effects due to the non-exact output voltage of the inverter are at least substantially reduced. A separate voltage measurement may be unnecessary.

In principle, it is conceivable to apply the second, higher voltage to the machine for a relatively long time, so that the increased current flow results in corresponding heating and thus influencing of the resistance in the connection region of the electrical machine. The resistance then determined could be compared to a specified ^differently surrounded or at the beginning of use of the machine measured, stored resistance value in order to be able to determine any increase of the resistance. A ^¬ be Sonder's simple and elegant solution arises, however, when the resistance determination is repeated at least once and the resistance values obtained are compared. In this case, it is particularly preferred if the applied voltages increases the ^¬ until generally a rated current flows in the machine. If repetitions of these abnormal, excessive temperature rise at any junction resulting in the area of power supply to the machine, the associated increased resistance would certainly be detected and displayed Kgs ^¬ NEN.

Tests have shown here that it is sufficient for a reliable investi ^¬ monitoring for possible contact faults when the Mes ^¬ measurements during a measurement period of eg 120s preferably continuously or second-wise be repeated.

The measurements are preferably carried out before each commissioning of the machine; in principle, be signed ^¬ resistance determination can also be in operation, but only in specific operating phases, namely when the machine will be carried out.

Accordingly, it is of particular advantage if the measurements and resistance measurements are carried out with unloaded, stationary machine.

The present technology is particularly advantageous in ^{multi-¬-phase} machines, in particular three-phase machines, to apply, in which case the measurements and resistivity determinations and comparisons are performed individually for each phase. The resistance values obtained for the individual phases are then evaluated not only isolated for each phase in isolation, but also advantageously compared with one another with regard to any asymmetrical increase in resistance.

In these resistance determinations, the (three) current sensors already present in the individual phases are preferably used directly for the current measurement; However, it is also conceivable to use only two phase current sensors, in combination with a current sum detection, to determine the individual, three phase currents and, subsequently, the three phase resistances. teln.

In particular, a particularly simple procedure for error detection can be achieved here if the respective phase resistances are transformed into a pointer form, in a complex plane.

Alternatively, a complex pointer can also be formed directly by measuring all the sensors (or at least two sensors), ie. Thus, three complex pointers are obtained for the phase values of the resistors. The directions of the three hands can also be different from the phase directions (0 °, 120 °, 240 °) in an asymmetric arrangement.

In terms of apparatus, preferably, the measuring arrangement, a vector transformation unit which is adapted to the respective phases of resistors in a link form to transformie ^¬ ren.

As a result, the obtained phase-related resistance pointer can then be spatially added, to which a suitable Addi ^¬ tion unit with the vector transformation unit can be connected, and then resulting single vector - which is ideally zero - can then as an error Indicator are used.

The invention will be described below with reference to particularly preferred embodiments, to which it should not be limited, and with reference to the drawings even further erläu ^¬ tert. In detail, in the drawing:

Figure 1 is a schematic block diagram of a system with Um ^¬ judge and electrical machine (induction machine), and with a control (regulation) and measuring system.

FIG. 2 is a circuit diagram of a device for detecting contact failures in a system approximately according to FIG. 1; FIG.

3 phase-related resistance values and an error indication in a complex level, for a properly functioning machine;

Fig. 4 is a corresponding illustration of a fault indicator in a complex plane, in the case of a contact failure in a single phase;

Fig. 5 in part charts A, B and C, the profile of the temperature (Fig. 5A) and the course of a phase current (Fig. 5B), in each case for the case of a properly functioning Ma ^¬ machine in solid line and in the case a contact error, dashed line; and - in Figure 5C - the course of the current difference at a contact error, each for the duration of a measurement interval.

FIG. 6 is a graph showing the magnitude of an error indicator, in a first section without filtering and in a second section with low-pass filtering; FIG.

7 shows a schematic representation of a complex error indicator as a function of time, on the one hand for a properly functioning system and on the other hand for the case of an HCP error; and

Fig. 8 in a corresponding to Fig. 7 graph, the magnitude of the fault indicator (in arbitrary units) over time, with a dotted line in the event of a properly func ^¬ alternating system (in solid line in case of contact failure HCP error), and dashed line in the case of an earlier on a test connector deliberately for the particular phase increased resistance value.

In Fig. 1 is generally an engine plant 1 with a three ^¬ polyphase induction machine 2 (hereinafter referred to briefly machine 2 be ^¬ records), with three only schematically illustrated windings 3 for phases U, V and W are illustrated. The machine 2 is fed by a converter 4, the corresponding phase voltages Vu, V _v and V _w with appropriate control by a control unit 5, which is part of a control (control) and measuring system 6 outputs. Usually, the control takes place, ie the Switch, the inverter 4 by means of PWM.

Between the inverter 4 and the machine 2 current sensors Su, S _v and S _w for measuring the phase currents iu, i _v and i _w are provided übli ^¬ cher manner. By means of this detection of the phase currents iu, i _v and i _w , a regulation, for example for regulating the power or the current consumption of the machine 2, can also be carried out with the aid of the system 6 instead of a mere activation of the converter 4.

As far as the engine plant 1 so that no further explanations are required for this purpose is previously described itself forth ^¬ kömmlich.

As already mentioned, irregularities in the voltage and hence the current supply can arise due to the most diverse causes, including switching operations and in particular converter dead times. The voltages V actually applied to the windings 3 of the machine 2 are therefore not necessarily constant, symmetrical output voltages of the converter 4. Therefore, if a simple resistance measurement were carried out so as to be able to detect any increases in resistance in the connection between the converter 4 and the machine 2 , it would be necessary to provide corresponding voltage sensors in addition to the machine 2. Such a resistance measurement would be carried out to detect any increases in contact resistance, generally contact errors, in the leads to the windings 3 of the machine 2, here the

various elements, such as terminals, fuses, breakers, cables, etc., are given. In order to eliminate these phenomena or at least eliminate them as much as possible, a multiple current measurement is now provided, which is connected to the corresponding drive voltages V of the converter 4 in order to perform a resistance determination.

Specifically, in the example shown, voltage phasors with the same direction but different sizes are applied by the inverter 4. The measurement is preferably carried out at a standstill ^¬ the machine is, without load and without flux. Since only the resistance value is determined and only stationary end values are taken into account, the resulting currents also have the same direction. More generally, a first clamping ^¬ voltage Vi of the converter 4 leads to a first current ii and a two ^¬ te, higher voltage V ₂ to a current i. ₂ The above

cited effects that otherwise affect the resistance measurement can now be eliminated by forming the differences _Δν = V ₂ -V i and Δ _± = i ₂ -ii. From this, the resistance R = _Δν / Δ _± can then be calculated.

Such a resistance value determination is now carried out in the present example for each phase U, V and W, so that all the phase resistances can not only be compared individually but also combined with one another. In this way symmetrical influences (stator) can be reduced or elimi ^¬ ned, and a representation of phase balance he will keep ^¬.

According to FIG. 1, the resistance measurement according to FIG. 1 will now be described with a measuring arrangement 7 belonging to the control and measuring system 6, which is to be explained in more detail below with reference to FIG. 2 and which is connected to the current sensors Su, S _v and S _w above principle for all three phases U, V and W.

First, for example, a voltage in the phase U is applied to the machine 2, and the current response is measured using the sensor Su. (In principle, all three current sensors S can also be used for the current measurement in order to reduce measurement tolerances in the individual sensors S.) Then, a second, higher voltage vector is applied in the same phase direction, and the current is detected again. This is shown in FIG. 2 illustrates in more detail, schematically showing the U-phase, the Ge ^¬ nerierung the voltage phasor at V _ux and V _u2 by appropriate control of the inverter 4 and generally detection means 5 'for the predetermined drive voltages is shown and are. The voltage pointers are thus those as they are generated by the on ^¬ control of the inverter 4 as target voltages. In a corresponding manner, the corresponding currents in and i _{u2 are} measured with the aid of the measuring arrangement 7. The power obtained ^¬ values are filtered in subsequent low pass filters 8 in, iu ₂ and thereafter supplied to a resistance detection unit 9U, where the aforementioned difference and quotient formation takes place to obtain, as output value, the resistance r _u in the phase U.

The procedure is analogous for the phases V and W so as to obtain the resistance values r _v and r _w via resistance determination units 9V and 9W (in general "9") These values are also referred to as "resistance ^pointers " the respective phase resistances are representative, but not comparable to other pointers such as voltage, current, or flux.

In a vector transformation unit 10 then these Wi ^¬ derstandswerte Tu, r _v and r _w of a scalar to a vector quantity with the appropriate amplitude, according to the ermit ^¬ telten value, and with a corresponding phase direction as the angular position determined in accordance with the following relationships: ru = ³ °

gj2n / 3

r _v = r _v ·

2Lw ⁼ r _we J4n / 3

However, it is also conceivable to proceed directly to complex vector quantities when determining the individual phase values of the resistors r _u , r _v , r _w .

In a subsequent step, a spatial addition of the resistance pointers r _n , r _v and r _{w is} carried out with the aid of an addition unit 11, wherein in the ideal case, if all the line and con ^¬ tact resistors in the system 1 are the same, so the phases are symmetrical in this regard, according to this addition, a zero vector is obtained. This zero vector thus indicates a proper state of the system 1, independent of symmetrical changes in resistance, for example as a result of temperature changes in the stator windings.

This state is schematically illustrated in Fig. 3, where at U, V and W the endpoints of the resistance pointers are illustrated in a complex plane with real part (real) and imaginary part ("imag"). At zero point, this sym- geometry-case the ideal, error-free case, the "lack-indica ^¬ tor who is here equal to zero. This error indicator is here generally designated 12.

In FIG. 1, a connection module is now generally shown at 13, wherein the phase resistances r _u , r _v and r _{w are represented} symbolically in a summarized manner. In a test, such a connection or connection module 13 has actually been implemented, and for the W phase of the connection or contact resistance ^¬ stand r was changed _w, will be explained in more detail below, so a contact failure (by way of example for all stages) in the phase W to simulate.

Specifically, a 280 V-ll kW cage rotor induction machine 2 with an inverter 4 instal ^¬ profiled on a laboratory bench. The control or (control) and measuring system 6 has been realized with egg ^¬ NEM computer system in MATLAB / Simulink

was programmable. In the connection module 13, copper conductors with the same electrical resistance were initially attached to the realization of phase resistors r _u , r _v and r _w

Simulating contacts 13 _v , 13 _n and 13 _w , following which the resistance determinations and evaluations described above gave an error indicator = 0 as shown in the diagram of FIG. 3. The resistance of the copper lines or the supply line of inverter 4 to machine windings 3 was exemplary in all three phases 10.8 mü.

This measurement can be used as the reference, serving as the initial value for ord ^¬ voltage according functioning plant.

Specifically, this first measurement was performed with a small amplitude of the voltage phasors, wherein the second voltage V _{2 was} exemplarily four times as large as the first voltage Vi.

The copper compound for phase W in terminal ^module 13 (contact 13 _w ) was then exchanged for a compound with a higher resistance value, namely 18 mu m, which means an increase in the resistance value in phase W of about 60%. The error indicator 12 'in this case was correspondingly shifted in the complex plane in the direction of the W phase, s. Fig. 4 (in Fig. 4, the individual resistance pointers were not illustrated in detail for the sake of simplicity, but only the individual phase directions U, V and W). The shift of the error indicator 12 from the zero point, error indicator 12, to the third quadrant point 12 'clearly indicates an increased resistance in the phase W. As mentioned above, this error resulted from the replacement of the original copper interconnecting line with a higher resistance line in phase W, at comparatively low voltages, and with a measuring time of 5 s.

In another test, the copper conductor in the connection module 13 in phase W was replaced by a tin strip connection. In order to determine the resistance / temperature relationship, the temperature of this "tin bridge" 13 _w with the variable phase resistance r _w (see Fig. 1) was measured by means of a temperature sensor. See also the temperature measuring unit 14 schematically illustrated in Fig. 1. The tin bridge in phase W had an ohmic resistance at ambient temperature equal to one of the copper conductors in the other phases, ie 10.8 mu.

The measurement duration, ie the step voltage, after switching from the voltage Vi, the first voltage, to the second voltage V ₂ in each phase U, V and W, was 120 s by way of example.

In the diagrams A, B and C of FIG. 5, measurement results for such a fault simulation in the phase W are now shown by way of example. In the diagram of FIG. 5A, the temperature profile T _{w is} illustrated. The temperature of the "defective" contact ^¬ 13W, with the tin bridge in the phase W, rose according to the dashed line in Fig. 5A from about room temperature to about 300 ° C, whereas the temperature Tu, _{v of} the "healthy" contact points 13U, 13V hardly changed in phases U and V. In other words, the temperature rise in the phases U, V, s. The solid line T _{Uf v} in Fig. 5A, had a much ge ^¬ ringeren increase than the temperature profile T _w in the phase W. As a result, incidentally, in this test was an increase in the winding temperature in the phase W of 26 ° C. Determine 38 ° C, whereas the winding temperature in phases U and V was from 26 ° C to only 33 ° C.

During the same measurement interval, the current i _w in the case of the "faulty connection", ie the simulated contact error to the sequence of the tin bridge, decreased considerably more, s. the dashed line i _w 'in FIG. 5B, in relation to the solid line i _w in the case of non-defective connection, the current curves for the currents iu, iv being similar to the solid line shown in FIG. 5B.

For additional illustration, FIG. 5C illustrates the difference of the currents, Ai _w , for the case of the contact fault simulated in the phase W (tin bridge in the connection module 13), wherein it can be seen that the magnitude of this current difference A i _w during the measurement interval is relative strong increase; this also explains the large shift of the error indicator 12 'in Fig. 4 compared to the zero error indicator 12 in this diagram.

In another test, a voltage step duration of 30 s was provided, and the current measurement was carried out within this measurement period in each case with a sampling frequency of 5 kHz. In order to suppress the signal noise, a low-pass filter has generally been used, as also illustrated in Fig. 2 with the filters 8 in the measuring arrangement. Specifically, a software solution, ie a digital filter that performed a running averaging, was implemented here, specifically a 2FIR filter (Finite Impulse Response - non-recursive filter) with a window length of 1000 was used. The result of this Fil ^¬ esterification can be seen from Fig. 6, in which the amount of the error indicator is recorded over time, initially the amount is illustrated without filtering, and the filter was switched 8 at the time Ti, wherein then a more or less constant mean.

In Fig. 7 in a 3D representation of the error indicator on the complex plane is (where arbitrary units WUR basis ^¬) and illustrated as a function of time, namely on the one hand, at 12, for a properly working system, and at 12 'in the case of a "contact error", namely the Case where the resistor 13W has been replaced by a tin strip instead of a copper wire with the same resistance as in the other ^phases U and V (see Fig. 1). The height in the time axis T corresponds approximately to the pulse duration of 30 s.

Specifically, the two error indicators 12, 12 'are illustrated on the one hand in the complex base plane comparable to the diagrams of FIGS. 3 and 4 and the progression in time is shown at 12 and 12', respectively. It is an essential deviate ^¬ deviation from the zero error indicator 12 for the case of HCP error recognizable. It can also be seen here that the deviation is approximately in the direction of the phase W.

In the tests, the connection was then made in the phase W in the terminal module 13 with a copper wire with a comparatively higher resistance (52 mu m), which corresponds to an increase of about 480% compared to the other phases U, V. In Fig. 8, the size of the error indicator is now plotted in arbitrary units on the ordinate. With the dotted curve 15, the case of a Null-Fehlerindi ^¬ cator 12 is illustrated; the HCP situation illustrated by the solid line 16 shows how the error indicator amount increases as the duration of the measurement increases with the increased ^resistance . To complete the effect of the "contact error" described above is finally shown in Fig. 8 with a dashed line 17, wherein on ^¬ basis of this contact error no change in the amount of the error indicator during the measurement results.

Although the invention has been explained above with reference to particularly preferred exemplary embodiments, it goes without saying that further modifications and modifications are conceivable within the scope of the invention. For example, in Fig. 1 nor an output unit 20 such as a display, shown, or that is connected to the measuring device 7 on the one hand and with the temperature measuring unit 14 on the other hand to corresponding displays in ^¬ play, in diagram form as in Fig. 3, 4 or 5 to 8 can be shown. Furthermore, the described Tech ^¬ nik also for single-phase machines is applicable in principle, whereby then, of course, eliminate the pointer representation can and a simple, linear resistance determination, with application of the rising voltages as described results. In this case, a resistance value r is therefore used as the basis for the determination of a possible contact error in the system.

A particular advantage is that the technique described can be realized without additional Schaltungskompo ^¬ components would be required (the temperature sensors described were used primarily for testing purposes, but are not really necessary in practice) - a particularly favorable realization lies in a corresponding configuration or programming of a computer module (μΡ, μθ), which is already provided for the inverter control.

Claims

Claims:

1. A method for detecting contact miss to an electrical machine (2), which is fed by a converter (4), characterized in that with the aid of the inverter (4) time ^¬ lich successively a first (Vi) and (a ) second ge ^¬ genüber the first boosted voltage (V ₂₎ is applied, and the associated machine currents caused thereby (ii, i ₂₎ are measured, and (from the quotient of the difference _Δ ν) of the two voltages by the difference (Δ _± ) of the two currents, a value for the resistance (r) is determined.

2. The method according to claim 1, characterized in that the resistance determination is repeated at least once and the resistance values obtained are compared.

3. The method according to claim 2, characterized in that the voltages are increased until generally a rated current flows in the machine (2).

A method according to claim 2 or 3, characterized in that the measurements are taken during a measurement period of e.g. 120s are repeated continuously.

5. The method according to any one of claims 1 to 4, characterized in that the measurements and resistance measurements in unloaded, stationary machine (2) are performed.

6. The method according to any one of claims 1 to 5, characterized in that in the case of a multi-phase machine (2) the Messun ^¬ conditions and resistance determinations and comparisons for each phase (U, V, W) are performed.

7. The method according to claim 6, characterized in that for the individual phases (U, V, W) obtained resistance values are compared with each other in view of the possible asymmetric resisting ^¬ stand increase (r _u, r _v, r _w).

8. The method according to claim 6 or 7, characterized in that the respective phase resistances (r _u , r _v , r _w ) in a Zei- gerform (r_u, r _v , r _w ), in a complex plane, transformed ^¬ who.

9. The method according to claim 8, characterized in that the resulting phase-related resistance pointers are spatially added, wherein the resulting single vector is used as Fehlerindika ^¬ gate (12).

10. A device for detecting contact errors on one of a converter (4) fed electrical machine (2), with at least one current sensor (Su, S _v , S _w ) for detecting a voltage when applied to the machine (2) by the Inverter (4) caused machine current (iu, iv, iw) _r characterized by a with the current sensor (Su, S _v , S _w ) connected to the measuring arrangement (7) with detection means (5 ') for the inverter voltage and with a Resistance-determining unit (9), in order successively ^¬ ing applying two different voltages, wherein the second voltage is increased compared to the first, and wherein two different currents are effected by quotient of voltage difference by current difference, a machine connection resistance value ( r _n , r _v , r _w ).

11. The method according to claim 10, characterized in that the measuring arrangement (7) is adapted to repeat the resistance determination, preferably continuously, and to compare the resistance values obtained.

A method according to claim 11, characterized in that the inverter (4) is connected to a control arrangement (5) arranged to increase the voltages until a rated current generally flows in the machine (2).

13. The method according to any one of claims 10 to 12, characterized in that in the case of a multi-phase machine (2) per phase (U, V, W), a current sensor (iu, i _v , i _w ) provided and the measuring arrangement (7 ) is arranged to perform the measurements or resistance determinations and comparisons for each phase.

14. The device according to claim 13, characterized in that the measuring arrangement (7) has a vector transformation unit (10). which is set up, the respective phase Widerstän ^¬ de in a pointer shape (r_u, r _v, r _w), to transform into a complex plane.

A device according to claim 14, characterized in that associated with the vector transformation unit (10) is an addition unit (11) arranged to spatially add the resistance pointers and to output the resulting single vector as an error indicator (12).