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* GB780009 (A) Description: GB780009 (A) ? 1957-07-31 Improvements relating to regulating systems for dynamo-electric machines Description of GB780009 (A) PATENT SPECIFICATION Inventor: NiORIMIAN HOARRY 1SHAW Date of filing Complete Specification: June 10, 1955. Application Date: June 16, 1954. No. 17726/54. 1 --Complete Specification Published: July 31, 1957. Index at acceptance:-Class 38(4), R(4: 21A1A). International Classification:-G05f. - COM1PLETE SPECOIFlICATION Improvements relating to Regulating Systems for DynamoElectric Machines We, THE ENGLISH ELECTRIC COMPANY LIMITED, of Queens House, 2!8 Kingsway, London, W.C.2, a British Company, do hereby declare the invention, for which we pray that a patent may be granted to us,.and the method by which it is to be performed, to be particularly described in and by 'the following statement:This invention, relates to regulating systems for synchronous generators of the kind including an automatic voltage regulator arranged to control the excitation of the generator automatically so, as to maintain the output voltage of the generator substantially constant. It is well known that in such systems the synchronising torque of the generator may, under certain conditions, fall below that necessary to maintain the generator in synchronism with the system to which it is connected., This loss of synchronising torque may be due, for example, to the action of the automatic voltage regulator which, in attempting to maintain the generator output voltage constant with sudden loss of load, reduces the generator excitation belbw the stability limit. One object of the present invention is to provide an improved regulating system which incorporates means for automatically preventing reduction of the generator excitation below the stability limit.
According to the invention, in a regulating system for a synchronous generator of the kind including an automatic voltage regulator arranged to control the generator excitation automatically in, a sense to maintain a generator output voltage substantially constant, overriding automatic control means are 'arranged' to prevent reduction of generator excitation below.a value determined solely by the magnitude of the generator load current, which value increases with the magnitude of the generator load current and' vice versa. According to a preferred feature of the invention the overriding control means are arranged to respond to electrical quantities varying with generator excitation and the [Price 3s. 6fCiet' 4sCo magnitude of the generator load current respectively, and to boost the generator excitation automatically if the excitation should fall below a value determined by the actual magnitude of the generator load current or if the magnitude of the generator load current should exceed a value determined by the actual value of generator excitation. According to 'a further preferred feature of the invention the overriding control means are arranged to boost the excitation of the generator by applying an overriding control quantity to the automatic voltage regulator in, a sense to cause the regulator to increase the generator excitation. {According to yet another preferred feature of the invention the automatic voltage regulator comprises a magnetic amplifier having an output winding connected in circuit with excitation varying means for the generator and a control winding connected in a comparison circuit consisting of a substantially constant electrical reference source and an electric control source varying with generator output voltage, so as to be energised in 'a corrective sense in accordance with variation of generator output voltage from a predetermined value, said overriding control means being arranged to boost the generator excitation by injecting an electrical quantity into said comparision circuit. Other preferred features of the invention will appear from. the follovwing description with reference to the drawing accompanying the Provisional Specification which shows the simplified circuit diagram of a regulating system for a turbo generator embodying the invention in preferred form., Referring now to the drawing the generator G supplies the three phase system busbars S through a step-up transformer T1, the field winding Gf of the generator being supplied, from an exciter E having a self-excited field winding Esf and a control field winding arranged in two mutually opposing sections Ecf.1 and cf'2.. The self-excited field winding Esf is connected in circuit with a motor 780,009 operated rheostat MR which is remotely controlled through means, not shown, to provide alternative hand control of the
generator output voltage, whilst the two sections Ecfl, Ecf2 of the control field winding 'are supplied from a magnetic amplifier MA1 having a control winding MA.lc. The control winding of the magnetic amplifier MA1i is connected across the output terminals OT of a comparison circuit which is arranged to compare a voltage dependent on the average of the generator line voltages with a voltage drop due to a constant reference current flowing through resistors. The circuit comprises, in series relationship, a constant current reference source IR, the star connected secondary winding of a transformer T2, dry plate rectifiers DR1, loading resistors R1 and R2, and a variable resistor VR1. The delta-connected primary winding of the transformer T2 is supplied from the generator G through a transformer T3 having a star-connected primary winding and a delta-connected secondary winding. The rectified output voltage of the transformer T2 is thus dependent on the average of the generator line voltages. In operation, the variable resistor VR1 is set so that, at the desired generator output voltage, the total voltage drop across the resistors R1, R2 and VR1 is substantially equal in magnitude and opposite in polarity to the voltage output derived from the rectifiers DR1. Under these conditions no potential difference will appear across the output terminals OT of the comparison circuit, and, the control winding MAlc of the magnetic amplifier MA1i will not be energized. If now the generator output voltage should rise, then since the current in the comparison circuit, and thus the voltage drop across the three resistors therein, is maintained constant, a potential difference will be developed across the output terminals OT which will result in the energization of the control winding MAlc of the magnetic amplifier MA&. The magnetic amplifier is arranged so that when its control winding is energized in this way the amplifier develops an output which is applied to the section Ecfl of the control winding on the exciter so as to buck the selfexcited winding Esf. The excitation of the generator G, and thus its output voltage, will accordingly be reduced until a balanced condition is restored at which just sufficient potential difference is maintained across the output terminals OT of the comparison, circuit to provide sufficient energization of the section Ecfl of the control winding on the exciter E. On the other hand, if the generator line volts should fall, a potential difference of opposite polarity will be developed across the output terminals OT of the comparison circuit with a consequent energization in the opposite sense of the control winding MAlc of the magnetic amplifier MAl. Under these conditions the magnetic amplifier energizes the section Ecf2 of the control winding on the exciter E in
a sense to boost the self-excited winding Esf and thereby increase the generator output volts until a balanced condition 70 is once more restored. In order to prevent loss of synchronism a voltage is applied automatically across the resistor R2 in a sense to cause the generator voltage to rise suddenly if the stability limit 75 is approached. This voltage is derived from a magnetic amplifier MIA2 and is applied to the resistor R2 through a rectifier DR2. The magnetic amplifier has three control windings MA2a, MA2b and MA2c respectively. Winding MA2a is energized from the comparison circuit in accordance with the rectified output from the transformer T2, i.e. in accordance with the average of the generator line voltages, a variable resistor VR2 being 85 included in circuit with this winding. Winding MA2b is energized through a rectifier bridge RB from a current transformer IT in one line of the generator load circuit, i.e. in accordance with generator load current. 90 Smoothing circuits may be provided for smoothing the D.C. output of the rectifier. Winding MA2c is connected in series with a variable resistor VR3 across a resistor R3 in the excitation circuit of the generator G so as 95 to be energized in accordance with generator excitation. Windings MA2a and MA2c, as shown by the small arrows, act in the same direction whilst winding MA2b opposes these two windings. 100 The variable resistors VR2 and VR3 are preset so that, provided the generator load current does not exceed a limit value which varies with the generator excitation, increasing with increase thereof, the winding MA2b 105 will be overcome by the combined effect of the windings MA2a and MA2c and the magnetic amplifier MA2 will be biased back to minimum output. Under these conditions the rectifier DR2 will prevent the flow of reverse 110 current which would otherwise occur as a result of the normal voltage drop across the resistor R2 due to the constant circulating current being greater than the output current from the magnetic amplifier MA2. The magnetic amplifier therefore has no effect on the operation of the comparison circuit. If, however, the generator load current should exceed such a value that the winding MA2b overcomes the combined effect of the 120 windings MA2a and MA2c, the magnetic amplifier will develop a comparatively large voltage, causing a current to flow in the forward direction through the rectifier DR2 which will increase the voltage across the resistor R2. A potential difference will therefore be developed across the output terminals OT of the comparison circuit which will cause the magnetic amplifier MA1 to energize the boost winding Ecf2 of the exciter E. The excitation 130 q780,009 sense to cause the regulator to increase the generator excitation.
* Sitemap * Accessibility * Legal notice * Terms of use * Last updated: 08.04.2015 * Worldwide Database * 5.8.23.4; 93p

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780009

  • 1. * GB780009 (A) Description: GB780009 (A) ? 1957-07-31 Improvements relating to regulating systems for dynamo-electric machines Description of GB780009 (A) PATENT SPECIFICATION Inventor: NiORIMIAN HOARRY 1SHAW Date of filing Complete Specification: June 10, 1955. Application Date: June 16, 1954. No. 17726/54. 1 --Complete Specification Published: July 31, 1957. Index at acceptance:-Class 38(4), R(4: 21A1A). International Classification:-G05f. - COM1PLETE SPECOIFlICATION Improvements relating to Regulating Systems for DynamoElectric Machines We, THE ENGLISH ELECTRIC COMPANY LIMITED, of Queens House, 2!8 Kingsway, London, W.C.2, a British Company, do hereby declare the invention, for which we pray that a patent may be granted to us,.and the method by which it is to be performed, to be particularly described in and by 'the following statement:This invention, relates to regulating systems for synchronous generators of the kind including an automatic voltage regulator arranged to control the excitation of the generator automatically so, as to maintain the output voltage of the generator substantially constant. It is well known that in such systems the synchronising torque of the generator may, under certain conditions, fall below that necessary to maintain the generator in synchronism with the system to which it is connected., This loss of synchronising torque may be due, for example, to the action of the automatic voltage regulator which, in attempting to maintain the generator output voltage constant with sudden loss of load, reduces the generator excitation belbw the stability limit. One object of the present invention is to provide an improved regulating system which incorporates means for automatically preventing reduction of the generator excitation below the stability limit.
  • 2. According to the invention, in a regulating system for a synchronous generator of the kind including an automatic voltage regulator arranged to control the generator excitation automatically in, a sense to maintain a generator output voltage substantially constant, overriding automatic control means are 'arranged' to prevent reduction of generator excitation below.a value determined solely by the magnitude of the generator load current, which value increases with the magnitude of the generator load current and' vice versa. According to a preferred feature of the invention the overriding control means are arranged to respond to electrical quantities varying with generator excitation and the [Price 3s. 6fCiet' 4sCo magnitude of the generator load current respectively, and to boost the generator excitation automatically if the excitation should fall below a value determined by the actual magnitude of the generator load current or if the magnitude of the generator load current should exceed a value determined by the actual value of generator excitation. According to 'a further preferred feature of the invention the overriding control means are arranged to boost the excitation of the generator by applying an overriding control quantity to the automatic voltage regulator in, a sense to cause the regulator to increase the generator excitation. {According to yet another preferred feature of the invention the automatic voltage regulator comprises a magnetic amplifier having an output winding connected in circuit with excitation varying means for the generator and a control winding connected in a comparison circuit consisting of a substantially constant electrical reference source and an electric control source varying with generator output voltage, so as to be energised in 'a corrective sense in accordance with variation of generator output voltage from a predetermined value, said overriding control means being arranged to boost the generator excitation by injecting an electrical quantity into said comparision circuit. Other preferred features of the invention will appear from. the follovwing description with reference to the drawing accompanying the Provisional Specification which shows the simplified circuit diagram of a regulating system for a turbo generator embodying the invention in preferred form., Referring now to the drawing the generator G supplies the three phase system busbars S through a step-up transformer T1, the field winding Gf of the generator being supplied, from an exciter E having a self-excited field winding Esf and a control field winding arranged in two mutually opposing sections Ecf.1 and cf'2.. The self-excited field winding Esf is connected in circuit with a motor 780,009 operated rheostat MR which is remotely controlled through means, not shown, to provide alternative hand control of the
  • 3. generator output voltage, whilst the two sections Ecfl, Ecf2 of the control field winding 'are supplied from a magnetic amplifier MA1 having a control winding MA.lc. The control winding of the magnetic amplifier MA1i is connected across the output terminals OT of a comparison circuit which is arranged to compare a voltage dependent on the average of the generator line voltages with a voltage drop due to a constant reference current flowing through resistors. The circuit comprises, in series relationship, a constant current reference source IR, the star connected secondary winding of a transformer T2, dry plate rectifiers DR1, loading resistors R1 and R2, and a variable resistor VR1. The delta-connected primary winding of the transformer T2 is supplied from the generator G through a transformer T3 having a star-connected primary winding and a delta-connected secondary winding. The rectified output voltage of the transformer T2 is thus dependent on the average of the generator line voltages. In operation, the variable resistor VR1 is set so that, at the desired generator output voltage, the total voltage drop across the resistors R1, R2 and VR1 is substantially equal in magnitude and opposite in polarity to the voltage output derived from the rectifiers DR1. Under these conditions no potential difference will appear across the output terminals OT of the comparison circuit, and, the control winding MAlc of the magnetic amplifier MA1i will not be energized. If now the generator output voltage should rise, then since the current in the comparison circuit, and thus the voltage drop across the three resistors therein, is maintained constant, a potential difference will be developed across the output terminals OT which will result in the energization of the control winding MAlc of the magnetic amplifier MA&. The magnetic amplifier is arranged so that when its control winding is energized in this way the amplifier develops an output which is applied to the section Ecfl of the control winding on the exciter so as to buck the selfexcited winding Esf. The excitation of the generator G, and thus its output voltage, will accordingly be reduced until a balanced condition is restored at which just sufficient potential difference is maintained across the output terminals OT of the comparison, circuit to provide sufficient energization of the section Ecfl of the control winding on the exciter E. On the other hand, if the generator line volts should fall, a potential difference of opposite polarity will be developed across the output terminals OT of the comparison circuit with a consequent energization in the opposite sense of the control winding MAlc of the magnetic amplifier MAl. Under these conditions the magnetic amplifier energizes the section Ecf2 of the control winding on the exciter E in
  • 4. a sense to boost the self-excited winding Esf and thereby increase the generator output volts until a balanced condition 70 is once more restored. In order to prevent loss of synchronism a voltage is applied automatically across the resistor R2 in a sense to cause the generator voltage to rise suddenly if the stability limit 75 is approached. This voltage is derived from a magnetic amplifier MIA2 and is applied to the resistor R2 through a rectifier DR2. The magnetic amplifier has three control windings MA2a, MA2b and MA2c respectively. Winding MA2a is energized from the comparison circuit in accordance with the rectified output from the transformer T2, i.e. in accordance with the average of the generator line voltages, a variable resistor VR2 being 85 included in circuit with this winding. Winding MA2b is energized through a rectifier bridge RB from a current transformer IT in one line of the generator load circuit, i.e. in accordance with generator load current. 90 Smoothing circuits may be provided for smoothing the D.C. output of the rectifier. Winding MA2c is connected in series with a variable resistor VR3 across a resistor R3 in the excitation circuit of the generator G so as 95 to be energized in accordance with generator excitation. Windings MA2a and MA2c, as shown by the small arrows, act in the same direction whilst winding MA2b opposes these two windings. 100 The variable resistors VR2 and VR3 are preset so that, provided the generator load current does not exceed a limit value which varies with the generator excitation, increasing with increase thereof, the winding MA2b 105 will be overcome by the combined effect of the windings MA2a and MA2c and the magnetic amplifier MA2 will be biased back to minimum output. Under these conditions the rectifier DR2 will prevent the flow of reverse 110 current which would otherwise occur as a result of the normal voltage drop across the resistor R2 due to the constant circulating current being greater than the output current from the magnetic amplifier MA2. The magnetic amplifier therefore has no effect on the operation of the comparison circuit. If, however, the generator load current should exceed such a value that the winding MA2b overcomes the combined effect of the 120 windings MA2a and MA2c, the magnetic amplifier will develop a comparatively large voltage, causing a current to flow in the forward direction through the rectifier DR2 which will increase the voltage across the resistor R2. A potential difference will therefore be developed across the output terminals OT of the comparison circuit which will cause the magnetic amplifier MA1 to energize the boost winding Ecf2 of the exciter E. The excitation 130 q780,009 sense to cause the regulator to increase the generator excitation.
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