DE3706932C2 - - Google Patents

Description

The invention relates to a method for auxiliary voltage-free Determine the insulation resistance according to the preamble of Claim 1.

A wide variety of methods for determining the insulation resistance without auxiliary voltage are known. B. from
the AT-PS 2 75 640,
DE-OS 15 13 460,
the DD-PS 52 78 and T. Kornas:
the rotor earth fault protection for synchronous machines of high performance; Electrical engineering and mechanical engineering, year 101 (1985), issue 10, pp. 468 to 471.

In AT-PS 2 75 640, on which the preamble of claim 1 is based, is an arrangement consisting of a between rotor mass and positive connection of the field winding switched encoder winding and a stator-side receiver winding specified. When an earth fault occurs, Current through the encoder winding, which in the receiver winding generates a signal voltage. This because of its simplicity advantageous device for the detection of connections however disadvantages. For one thing, earth faults in immediate vicinity of the donor winding was not measured are as specified in the AT-PS 2 75 640 itself Potential course along the field winding is recognizable. To the  others allow this arrangement because the current flows through the encoder winding not only on the amount of earth fault resistance but also depends on the earth fault location, no quantitative earth fault detection.

The arrangement mentioned in DE-OS 15 13 460 differs differ from the above only by the location of the coupling (Star point of the excitation generator) and the coupling type (capacitive). This arrangement thus has the same advantages and disadvantages such as those described in AT-PS 2 75 640.

As a criterion for an earth fault in the procedure after the contribution by T. Kornas, E. u. M., 1983, pp. 468 to 471, the pulse length a pulsating earth current, which originates from the star point of a Capacitor arrangement against rotor ground flows used. A Earth fault detection according to this criterion is due in particular its simple evaluation is an advantage, but leaves no quantitative measurements because the pulse length mentioned is not depends on the size of the earth fault resistance and the amplitude the pulses not only from the earth fault resistance but also depend on the - unknown - earth fault location.

DD-PS 52 78 describes a method for determining the earth fault in the rotor of a generator by mutual voltage measurement between the connections of the field winding and the Runner earth specified. This procedure allows for generators with DC excitation machine also the quantitative determination the earth fault resistance; but it cannot be done easily transferred to rectifier-excited generators, because the excitation device on the one hand by a circuit section in which only AC voltages occur, is expanded by the other  Behavior of the rectifier bridge of the excitation voltage AC components are superimposed. These AC voltages affect that Measurement result, since it not only earth currents via the earth fault resistance but also through the earth's capacity, d. H. the Measurement becomes dependent on machine parameters and the temperature the excitation device.

The invention has for its object one of the parameters independent of the machine (especially the earth's capacity) specify a quantitative determination of the earth fault resistance and thus the observation of damage development allowed.

The object is achieved by the characterizing features in claim 1 solved.

It is particularly advantageous that based on the evaluation of the direct components of the earth currents the process regardless of machine parameters and that existing Generator systems can be easily retrofitted. At the same time earth fault resistances can be determined according to their size, whereby damage monitoring and scheduling of Maintenance appointments becomes possible.

A useful training is characterized in claim 2.

By comparing the alternately measured earth currents there are additional statements about the location of the earth fault win; if different earth currents are measured, there is an earth fault in the excitation winding of the generator and can be in Specify percent of the field winding length. For the planning of Knowledge of a damage site is important for maintenance work.  It is particularly advantageous, however, that if a variable Fault location is observed, from this on a multiple Earth fault can be closed.

The invention is illustrated below in the Figure illustrated embodiment explained in more detail.  

The excitation device of synchronous machines is usually as shown in the figure.

An earth fault protection device, which works according to the method of claim 1 and 2, consists for example of two current measuring points SM 1 and SM 2 , which are alternately connected via the analog switches S 1 and S 2 between connections of the field winding and rotor earth. The earth currents IE 1 and IE 2 measured in this way depend on the size and location of an insulation fault RF . In any case, the amount of the resistance RF (in the case of several errors, the amount of the parallel connection of the earth fault resistors) can be calculated from the equal proportions of the earth currents IE 1 and IE 2 by applying Kirchhoff's law and meshes and Ohm's law to the measuring circuit. If the earth currents IE 1 and IE 2 are identical, the fault location is in the three-phase winding or in the middle of the field winding (differentiation possible by evaluating the alternating component). If the earth currents IE 1 and IE 2 are different, the fault location is in the field winding and can be specified as a percentage of the field winding length 1 ERR .

Claims (2)

1. A method for determining the insulation resistance between the rectifier-fed, potential-free excitation device and the surrounding rotor earth of synchronous machines by measuring earth currents,
characterized,
that earth currents are measured alternately at two connections and
that the insulation resistance is determined quantitatively from the equal proportions of the earth currents. 2. The method according to claim 1, characterized, that by comparing the amounts of the DC components the location of the Insulation resistance is determined.