CS243027B1 - Connection for monitoring the rotor rotor phase currents of the ring motor - Google Patents

Abstract

The connection is particularly suitable where two or more slip-ring motors operate in a mechanism that connects them firmly or flexibly. Monitoring of fault conditions even at slip frequencies f</2 Hz is carried out by rectifying the d values on the resistors in the individual phases - using extremely high filtering. Three sensitive relays are used for evaluation, so that the individual rotor phases are indicated separately. The sensitivity can be adjusted, for example, so that a current drop below 0.25 I of the nominal is indicated.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a circuit for monitoring the phase rotor currents of a ring motor, in particular to monitor the rotor currents of individual phases of an asynchronous ring motor with a permanent slip resistance.

Monitoring the rotor currents of the individual phases has its merit in cases where two or more motors operate in a mechanism that connects them to each other, either firmly or flexibly, e.g. conveyor belt.

Direct monitoring of rotor currents has not been carried out yet, as it is difficult to indicate the voltage with a slip frequency f «ζ 2 Hz.

Interruption of some phase of the rotor circuit results in parasitic moments, but the mechanically coupled motor continues to rotate.

The problematic indication of rotor failure can be done only by monitoring the load of the primary winding of the stators of individual motors.

These disadvantages are eliminated by wiring for phase rotor current monitoring *

Its essence is that the first pole of the first stage filtration capacitors is connected via resistors of the second stage of filtration to the first pole of the second stage filtration capacitors and the first terminals of the adjusting potentiometers.

The middle terminals and second terminals of the adjusting potentiometers are connected to the first pole of the third stage filtration capacitors and the first input of the sensitive relays.

The second pole of the first stage filtration capacitors is connected to the second pole of the second and third stage filtration capacitors and to the second input of the sensitive relays.

The advantage of this circuit is the ability to operate at the slip frequencies of the asynchronous motor, which can be in the range of f = 2 to 0.2 Hz.

Another advantage is the resolution of the phase in which the fault occurred. No similar or known protection is available.

In the attached drawing, the circuit according to the invention is schematically illustrated.

Asynchronous ring motor χ has slip resistors permanently connected to the rotor .2,1 2 ₂ ,

-3 ’

In parallel to the slip resistors 2, 2, 2 ^, they are connected via fuses 3, 3 ^, 3 ^,

-5 '-6' ^odbo2né resistors 4 ,, 4 ₂ K'těmto branch resistors 4 _', 4 _2, 4-are connected via a protective resistor _5 _t, 5 _2, rectifier .6 ,, 6 _2> 6 ^.

To their DC outputs, capacitors 7, 7, ₂ , 7j of the first filtration stage are connected.

The first pole of the capacitor 2 ,, 2-Ί> Beer filtration stage is connected through resistors IQ ,, ₂ 1_0, 1_0-j of the second stage of filtration to the first terminal of the capacitor 8 ,, 8 ₂ 8j second filtration step and the first clamp adjusting potentiometers ϋ. , jj. ₂ »H3 ·

Central terminal and the second terminal of adjustment potentiometers _{LI) t} 1J _2, lj are connected to the first pole of capacitors _9,1 _9 _2>.? ·> Third grade filtration and a first input of sensitive relays

Nov 12 ·

The second pole of the capacitor J7 ,, 7 _2, 7 ^ the first filtration stage is connected to the second terminal of the capacitors 8, 8 _2> 8j second filtration step and the second pole of the capacitor, 9 _2, the third filtering stage and a second input responsive relay 12, 13 14

The function of the invention is as follows.

The individual slip resistor 2j, 2 _2, 2 voltage drops

Δϋ = R. I. 2 where R is the slip resistance

I ₂ rotor current circuit leading to the resistors _4 _2, 4 and the voltage drops of the resistors to regulate the rectifier,

6 ₂ -3 '3 ^SOU composed of diodes in the forward direction Imaje minimized loss.

Sensitive relay J2. JJ, £ 1 of the baffles 6 _1, 6 _2, 6-powered through resistor [O ,, jog 10j and the second filtration step adjustment Sliders H ,, 1_1 _2, ILj, which gives the necessary values for of these relays.

Sensitive relays 12, 13, 14 when a current in the respective phase current falls below the rotor wherein a rated current I _2n rotor circuit

Rectified frequency filtration in the range of f = 2 Hz to 0.2 Hz consists of three stages. The first stage consists of a protective resistor 5, _5 _2, 2} 7 ^ capacitors ^8, 7 _2, 7 ^ the first filtration step.

The second stage consists of resistors H3 ,, H> ₂ ^ 10 and second stage filter capacitors Sp 8 _2, 8j second stage filtration.

The third stage consists of adjusting Potentiometers 1J ,, £ _2, 1 & apos capacitors ₂ and ₂ _9> 2.3 third stage of filtration.

The feasibility of this circuitry is given by the use of sensitive relays 12, 13, 44.

Sensitive relay contacts 12, 13, 14 have low switching capability, so it is necessary to use RC cards to protect their contacts and to include intermediate switches. This circuit is no longer the subject of the invention.

For exposed drives it is advisable to monitor rotor currents even for ring motors working separately.

Claims (1)

SUBJECT OF THE INVENTION Circuit monitoring circuits for a ring motor with slip resistors connected to the rotor, branching resistors connected to the slip resistors to which they are connected via the rectifier protective resistors, with their first output capacitors connected to their DC outputs characterized in that the first pole of the capacitors (7j, 7 ₂ > 7 ^) of the first stage of filtration is connected via resistors (, 0 ^, 10 ₂ , 10 ^) of the second stage of filtration to the first half of the capacitors (8, Sj, 83) ) of the second stage of filtration and on the first terminal of the adjusting potentiometers (11 ,, 11 ₂ , 11 ₃ ), their middle outlet and second terminal of the adjusting potentiometers (11 ,, 11 ₂ , ΙΙ3Ϊ are connected to the first pole * of capacitors (9, , 9 _2, 9 ^) fil- third stage, the trace and a first input responsive ^relay! (12, 13, 14), while the second pole of the capacitor (7 ,, 7 _2, 7-j) of the first filtration stage is connected simultaneously to the second pole of the capacitor (8 ,, 8 _2, 83) of the second stage of filtration, a condenser (9 ,, 9 g, 9 ^ 5 the third stage of filtration and also to a second input responsive relay (12, 13, 14).