| H | SK | ELECTRICITY |
| H02 | KL | GENERATION, CONVERSION, OR DISTRIBUTION OF ELECTRIC POWER |
| H02P | UKL | CONTROL OR REGULATION OF ELECTRIC MOTORS, GENERATORS, OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS (structure of the starter, brake, or other control devices, see the relevant subclasses, e.g. mechanical brake F16D , mechanical speed regulator G05D , variable resistor H01C , starter switch H01H; systems for regulating electric or magnetic variables using transformers, reactors or choke coils G05F; arrangements structurally associated with motors, generators, dynamo-electric converters, transformers, reactors or choke coils, see the relevant subclasses, e.g. H01F , H02K; connection or control of one generator, transformer, reactor, choke coil, or dynamo-electric converter with regard to conjoint operation with similar or other source of supply H02J; control or regulation of static converters H02M) [4] |
| H02P 1/00 | HGR | Arrangements for starting electric motors or dynamo-electric converters (H02P 6/00 takes precedence) [4] |
| H02P 1/02 | UGR1 | |
| H02P 1/04 | UGR2 | | . . | Means for controlling progress of starting sequence in dependence upon time or upon current, speed, or other motor parameter |
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| H02P 1/06 | UGR3 | | . . . | Manually-operated multi-position starters |
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| H02P 1/08 | UGR3 | | . . . | Manually-operated on/off switch controlling power-operated multi-position switch or impedances for starting a motor |
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| H02P 1/10 | UGR3 | | . . . | Manually-operated on/off switch controlling relays or contactors operating sequentially for starting a motor (sequence determined by power-operated multi-position switch H02P 1/08) |
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| H02P 1/12 | UGR3 | | . . . | Switching devices centrifugally operated by the motor |
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| H02P 1/14 | UGR3 | | . . . | Pressure-sensitive resistors centrifugally operated by the motor |
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| H02P 1/16 | UGR1 | | . | for starting dynamo-electric motors or dynamo-electric converters |
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| H02P 1/18 | UGR2 | | . . | for starting an individual dc motor |
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| H02P 1/20 | UGR3 | | . . . | by progressive reduction of resistance in series with armature winding |
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| H02P 1/22 | UGR3 | | . . . | in either direction of rotation |
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| H02P 1/24 | UGR2 | | . . | for starting an individual ac commutator motor (starting of ac/dc commutator motors H02P 1/18) |
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| H02P 1/26 | UGR2 | | . . | for starting an individual polyphase induction motor |
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| H02P 1/28 | UGR3 | | . . . | by progressive increase of voltage applied to primary circuit of motor |
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| H02P 1/30 | UGR3 | | . . . | by progressive increase of frequency of supply to primary circuit of motor |
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| H02P 1/32 | UGR3 | | . . . | by star/delta switching |
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| H02P 1/34 | UGR3 | | . . . | by progressive reduction of impedance in secondary circuit |
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| H02P 1/36 | UGR4 | | . . . . | the impedance being a liquid resistance |
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| H02P 1/38 | UGR3 | |
| H02P 1/40 | UGR3 | | . . . | in either direction of rotation |
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| H02P 1/42 | UGR2 | | . . | for starting an individual single-phase induction motor |
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| H02P 1/44 | UGR3 | | . . . | by phase-splitting with a capacitor |
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| H02P 1/46 | UGR2 | | . . | for starting an individual synchronous motor |
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| H02P 1/48 | UGR3 | |
| H02P 1/50 | UGR3 | | . . . | by changing over from asynchronous to synchronous operation (H02P 1/48 takes precedence) |
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| H02P 1/52 | UGR3 | | . . . | by progressive increase of frequency of supply to motor |
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| H02P 1/54 | UGR2 | | . . | for starting two or more dynamo-electric motors |
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| H02P 1/56 | UGR3 | |
| H02P 1/58 | UGR3 | |
| H02P 3/00 | HGR | Arrangements for stopping or slowing electric motors, generators, or dynamo-electric converters (H02P 6/00 takes precedence) [2, 4] |
| H02P 3/02 | UGR1 | |
| H02P 3/04 | UGR2 | | . . | Means for stopping or slowing by a separate brake, e.g. friction brake, eddy-current brake (brakes F16D , H02K 49/00) [2] |
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| H02P 3/06 | UGR1 | | . | for stopping or slowing an individual dynamo-electric motor or dynamo-electric converter [2] |
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| H02P 3/08 | UGR2 | | . . | for stopping or slowing a dc motor [2] |
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| H02P 3/10 | UGR3 | | . . . | by reversal of supply connections |
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| H02P 3/12 | UGR3 | | . . . | by short-circuit or resistive braking |
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| H02P 3/14 | UGR3 | | . . . | by regenerative braking |
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| H02P 3/16 | UGR3 | | . . . | by combined electrical and mechanical braking |
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| H02P 3/18 | UGR2 | | . . | for stopping or slowing an ac motor [2] |
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| H02P 3/20 | UGR3 | | . . . | by reversal of phase sequence of connections to the motor |
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| H02P 3/22 | UGR3 | | . . . | by short-circuit or resistive braking |
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| H02P 3/24 | UGR3 | | . . . | by applying dc to the motor |
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| H02P 3/26 | UGR3 | | . . . | by combined electrical and mechanical braking |
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| H02P 5/00 | HGR | Arrangements for speed regulation of electric motors wherein the motor speed is measured and compared with a given physical value so as to adjust the motor speed |
| H02P 5/04 | UGR1 | | . | for speed regulation of an individual motor by means of a separate brake |
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| H02P 5/05 | UGR1 | | . | characterised by the use of reluctance motors [6] |
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| H02P 5/06 | UGR1 | | . | for speed regulation of an individual dc dynamo-electric motor by varying field or armature current |
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| H02P 5/08 | UGR2 | | . . | using centrifugal devices, e.g. switch, resistor |
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| H02P 5/10 | UGR2 | |
| H02P 5/12 | UGR2 | | . . | using discharge tubes or semiconductor devices (H02P 5/08 takes precedence) [4] |
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| H02P 5/14 | UGR3 | | . . . | using discharge tubes |
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| H02P 5/16 | UGR3 | | . . . | using semiconductor devices |
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| H02P 5/162 | UGR4 | | . . . . | controlling field supply only [4] |
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| H02P 5/165 | UGR4 | | . . . . | controlling armature supply only [4] |
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| H02P 5/168 | UGR5 | | . . . . . | using variable impedance [4] |
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| H02P 5/17 | UGR5 | | . . . . . | using pulse modulation [4] |
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| H02P 5/172 | UGR5 | | . . . . . | using static converters, e.g. ac to dc [4] |
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| H02P 5/175 | UGR6 | | . . . . . . | of the kind having one thyristor or the like in series with the power supply and the motor [4] |
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| H02P 5/178 | UGR4 | | . . . . | controlling armature and field supply [4] |
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| H02P 5/18 | UGR2 | | . . | using magnetic devices with controllable degree of saturation, i.e. transductors |
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| H02P 5/20 | UGR2 | | . . | using armature-reaction-excited machines, e.g. metadyne, amplidyne, rototrol |
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| H02P 5/22 | UGR2 | | . . | using Ward-Leonard set |
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| H02P 5/24 | UGR3 | | . . . | in which only the generator field is controlled |
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| H02P 5/26 | UGR3 | | . . . | in which both generator and motor fields are controlled |
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| H02P 5/28 | UGR1 | | . | for speed regulation of an individual ac motor by varying stator or rotor current |
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| H02P 5/30 | UGR2 | | . . | using centrifugal devices, e.g. switch, resistor |
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| H02P 5/32 | UGR2 | | . . | using a periodic interrupter (H02P 5/30 takes precedence) |
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| H02P 5/34 | UGR2 | | . . | by varying frequency of supply to rotor or stator |
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| H02P 5/36 | UGR2 | | . . | using discharge tubes or semiconductor devices |
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| H02P 5/38 | UGR3 | | . . . | using discharge tubes |
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| H02P 5/40 | UGR3 | | . . . | using semiconductor devices (vector- or field-oriented control H02P 21/00) [6] |
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| H02P 5/402 | UGR4 | | . . . . | controlling supply voltage (H02P 5/418 takes precedence) [4] |
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| H02P 5/405 | UGR4 | | . . . . | controlling secondary impedance [4] |
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| H02P 5/408 | UGR4 | | . . . . | controlling supply frequency (H02P 5/418 takes precedence) [4] |
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| H02P 5/41 | UGR5 | | . . . . . | using dc to ac converters [4] |
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| H02P 5/412 | UGR5 | | . . . . . | using ac to ac converters without intermediate conversion to dc [4] |
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| H02P 5/415 | UGR4 | | . . . . | controlling slip energy [4] |
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| H02P 5/418 | UGR4 | | . . . . | for regulating commutator motors [4] |
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| H02P 5/42 | UGR2 | | . . | using magnetic devices with controllable degree of saturation, i.e. transductors |
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| H02P 5/44 | UGR2 | | . . | using brush shifting arrangements |
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| H02P 5/46 | UGR1 | | . | for speed regulation of two or more dynamo-electric motors in relation to one another |
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| H02P 5/48 | UGR2 | | . . | by comparing mechanical values representing the speeds |
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| H02P 5/50 | UGR2 | | . . | by comparing electrical values representing the speeds |
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| H02P 5/52 | UGR2 | | . . | additionally providing control of relative angular displacement |
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| H02P 6/00 | HGR | Arrangements for controlling synchronous motors or other dynamo-electric motors with electronic commutators in dependence on the rotor position; Electronic commutators therefor (H02P 8/00 takes precedence; vector- or field-oriented control H02P 21/00) [3, 4, 6] |
| H02P 6/04 | UGR1 | | . | Arrangements for controlling or regulating speed or torque of more than one motor [6] |
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| H02P 6/06 | UGR1 | | . | Arrangements for speed regulation of a single motor wherein the motor speed is measured and compared with a given physical value so as to adjust the motor speed [6] |
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| H02P 6/08 | UGR1 | | . | Arrangements for controlling the speed or torque of a single motor [6] |
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| H02P 6/10 | UGR2 | | . . | providing reduced torque ripple; controlling torque ripple [6] |
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| H02P 6/12 | UGR1 | | . | Monitoring commutation; Providing indication of commutation failure [6] |
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| H02P 6/14 | UGR1 | | . | Electronic commutators [6] |
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| H02P 6/16 | UGR2 | | . . | Circuit arrangements for detecting position (structural arrangement of position sensors H02K 29/06) [6] |
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| H02P 6/18 | UGR3 | | . . . | without separate position detecting element, e.g. using back-emf in windings [6] |
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| H02P 6/20 | UGR1 | |
| H02P 6/22 | UGR1 | | . | Arrangements for starting in a selected direction of rotation [6] |
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| H02P 6/24 | UGR1 | | . | Arrangements for stopping [6] |
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| H02P 7/00 | HGR | Arrangements for controlling the speed or torque of electric motors (H02P 1/00 to H02P 6/00 , H02P 8/00 take precedence; speed control in general G05D 13/62) [2] |
| H02P 7/01 | UGR1 | | . | adapted to be connected to two or more voltage or current supplies [5] |
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| H02P 7/04 | UGR1 | | . | for controlling an individual motor by means of a separate brake |
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| H02P 7/05 | UGR1 | | . | characterised by the use of reluctance motors [6] |
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| H02P 7/06 | UGR1 | | . | for controlling an individual dc dynamo-electric motor by varying field or armature current |
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| H02P 7/08 | UGR2 | | . . | by manual control without auxiliary power |
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| H02P 7/10 | UGR3 | |
| H02P 7/12 | UGR4 | | . . . . | Switching field from series to shunt excitation or vice versa |
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| H02P 7/14 | UGR3 | | . . . | of voltage applied to the armature with or without control of field |
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| H02P 7/18 | UGR2 | | . . | by master control with auxiliary power |
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| H02P 7/20 | UGR3 | | . . . | using multi-position switch, e.g. drum, controlling motor circuit by means of relays |
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| H02P 7/22 | UGR3 | | . . . | using multi-position switch, e.g. drum, controlling motor circuit by means of pilot-motor-operated multi-position switch or pilot-motor-operated variable resistance |
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| H02P 7/24 | UGR3 | | . . . | using discharge tubes or semiconductor devices |
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| H02P 7/26 | UGR4 | | . . . . | using discharge tubes |
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| H02P 7/28 | UGR4 | | . . . . | using semiconductor devices |
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| H02P 7/282 | UGR5 | | . . . . . | controlling field supply only [4] |
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| H02P 7/285 | UGR5 | | . . . . . | controlling armature supply only [4] |
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| H02P 7/288 | UGR6 | | . . . . . . | using variable impedance [4] |
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| H02P 7/29 | UGR6 | | . . . . . . | using pulse modulation [4] |
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| H02P 7/292 | UGR6 | | . . . . . . | using static converters, e.g. ac to dc [4] |
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| H02P 7/295 | UGR7 | | . . . . . . . | of the kind having one thyristor or the like in series with the power supply and the motor [4] |
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| H02P 7/298 | UGR5 | | . . . . . | controlling armature and field supply [4] |
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| H02P 7/30 | UGR3 | | . . . | using magnetic devices with controllable degree of saturation, i.e. transductors |
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| H02P 7/32 | UGR3 | | . . . | using armature-reaction-excited machines, e.g. metadyne, amplidyne, rototrol |
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| H02P 7/34 | UGR3 | | . . . | using Ward-Leonard arrangements |
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| H02P 7/36 | UGR1 | | . | for controlling an individual ac dynamo-electric motor by varying stator or rotor current |
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| H02P 7/38 | UGR2 | | . . | by manual control without auxiliary power |
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| H02P 7/40 | UGR3 | | . . . | using variable impedance in stator or rotor circuit |
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| H02P 7/42 | UGR3 | | . . . | using variable-frequency supply |
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| H02P 7/44 | UGR4 | | . . . . | wherein only rotor or only stator circuit is supplied with ac |
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| H02P 7/46 | UGR4 | | . . . . | wherein both rotor and stator circuits are supplied with ac, the frequency of supply to one circuit being variable |
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| H02P 7/48 | UGR3 | |
| H02P 7/50 | UGR3 | | . . . | by shifting the brushes of a commutator motor |
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| H02P 7/52 | UGR2 | | . . | by master control with auxiliary power |
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| H02P 7/54 | UGR3 | | . . . | using multi-position switch, e.g. drum, controlling motor circuit by means of relays |
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| H02P 7/56 | UGR3 | | . . . | using multi-position switch, e.g. drum, controlling motor circuit by means of pilot-motor-operated multi-position switch or pilot-motor-operated variable resistance |
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| H02P 7/58 | UGR3 | | . . . | using discharge tubes or semiconductor devices |
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| H02P 7/60 | UGR4 | | . . . . | using discharge tubes |
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| H02P 7/62 | UGR4 | | . . . . | using semiconductor devices (vector- or field-oriented control H02P 21/00) [6] |
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| H02P 7/622 | UGR5 | | . . . . . | controlling supply voltage (H02P 7/638 takes precedence) [4] |
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| H02P 7/625 | UGR5 | | . . . . . | controlling secondary impedance [4] |
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| H02P 7/628 | UGR5 | | . . . . . | controlling supply frequency (H02P 7/638 takes precedence) [4] |
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| H02P 7/63 | UGR6 | | . . . . . . | using dc to ac converters [4] |
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| H02P 7/632 | UGR6 | | . . . . . . | using ac to ac converters without intermediate conversion to dc [4] |
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| H02P 7/635 | UGR5 | | . . . . . | controlling slip energy [4] |
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| H02P 7/638 | UGR5 | | . . . . . | for controlling commutator motors [4] |
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| H02P 7/64 | UGR3 | | . . . | using magnetic devices with controllable degree of saturation, i.e. transductors |
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| H02P 7/66 | UGR3 | | . . . | using an ac generator to supply the motor, the motor being controlled by a control effected upon the generator |
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| H02P 7/67 | UGR1 | | . | for controlling two or more dynamo-electric motors [4] |
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| H02P 7/68 | UGR2 | | . . | for controlling two or more dc dynamo-electric motors |
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| H02P 7/685 | UGR3 | | . . . | electrically connected in series, i.e. carrying the same current [3] |
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| H02P 7/69 | UGR3 | | . . . | mechanically coupled by gearing [3] |
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| H02P 7/695 | UGR4 | | . . . . | Differential gearing [3] |
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| H02P 7/74 | UGR2 | | . . | for controlling two or more ac dynamo-electric motors |
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| H02P 7/747 | UGR3 | | . . . | mechanically coupled by gearing [3] |
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| H02P 7/753 | UGR4 | | . . . . | Differential gearing [3] |
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| H02P 7/80 | UGR2 | | . . | for controlling combinations of dc and ac dynamo-electric motors |
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| H02P 8/00 | HGR | Arrangements for controlling dynamo-electric motors rotating step by step [2, 6] |
| H02P 8/02 | UGR1 | | . | specially adapted for single-phase or bi-pole stepper motors, e.g. watch-motors, clock-motors [6] |
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| H02P 8/04 | UGR1 | | . | Arrangements for starting [6] |
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| H02P 8/06 | UGR2 | | . . | in selected direction of rotation [6] |
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| H02P 8/08 | UGR2 | | . . | Determining position before starting [6] |
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| H02P 8/10 | UGR2 | | . . | Shaping pulses for starting; Boosting current during starting [6] |
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| H02P 8/12 | UGR1 | | . | Control or stabilisation of current [6] |
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| H02P 8/14 | UGR1 | | . | Arrangements for controlling speed or speed and torque (H02P 8/12 , H02P 8/22 take precedence) [6] |
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| H02P 8/16 | UGR2 | | . . | Reducing energy dissipated or supplied [6] |
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| H02P 8/18 | UGR2 | | . . | Shaping of pulses, e.g. to reduce torque ripple [6] |
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| H02P 8/20 | UGR2 | | . . | characterised by bidirectional operation [6] |
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| H02P 8/22 | UGR1 | | . | Control of step size; Intermediate stepping, e.g. micro-stepping [6] |
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| H02P 8/24 | UGR1 | | . | Arrangements for stopping (H02P 8/32 take precedence) [6] |
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| H02P 8/26 | UGR2 | | . . | Memorising final pulse when stopping [6] |
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| H02P 8/28 | UGR2 | | . . | Disconnecting power source when stopping [6] |
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| H02P 8/30 | UGR2 | | . . | Holding position when stopped [6] |
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| H02P 8/32 | UGR1 | | . | Reducing overshoot or oscillation, e.g. damping [6] |
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| H02P 8/34 | UGR1 | | . | Monitoring operation (H02P 8/36 takes precedence) [6] |
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| H02P 8/36 | UGR1 | | . | Protection against faults, e.g. against overheating, step-out; Indicating faults (emergency protective arrangements with automatic interruption of supply H02H 7/08) [6] |
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| H02P 8/38 | UGR2 | | . . | the fault being step-out [6] |
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| H02P 8/40 | UGR1 | | . | Special adaptations for controlling two or more stepping motors [6] |
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| H02P 8/42 | UGR1 | | . | characterised by non-stepper motors being operated step by step [6] |
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| H02P 9/00 | HGR | Arrangements for controlling electric generators for the purpose of obtaining a desired output (Ward-Leonard arrangements H02P 7/34; feeding a network by two or more generators H02J; for charging batteries H02J 7/14) |
| H02P 9/02 | UGR1 | |
| H02P 9/04 | UGR1 | | . | Control effected upon non-electric prime mover and dependent upon electric output value of the generator (effecting control of the prime mover in general, see the relevant class for such prime mover) [2] |
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| H02P 9/06 | UGR1 | | . | Control effected upon clutch or other mechanical power transmission means and dependent upon electric output value of the generator (effecting control of the power transmission means, see the relevant class for such means) [2] |
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| H02P 9/08 | UGR1 | | . | Control of generator circuit during starting or stopping of driving means, e.g. for initiating excitation [2] |
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| H02P 9/10 | UGR1 | | . | Control effected upon generator excitation circuit to reduce harmful effects of overloads or transients, e.g. sudden application of load, sudden removal of load, sudden change of load [2] |
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| H02P 9/12 | UGR2 | | . . | for demagnetising; for reducing effects of remanence; for preventing pole reversal [2] |
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| H02P 9/14 | UGR1 | |
| H02P 9/16 | UGR2 | | . . | due to variation of ohmic resistance in field circuit, using resistances switched in or out of circuit step by step |
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| H02P 9/18 | UGR3 | | . . . | the switching being caused by a servomotor, measuring instrument, or relay |
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| H02P 9/20 | UGR2 | | . . | due to variation of continuously-variable ohmic resistance |
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| H02P 9/22 | UGR3 | | . . . | comprising carbon pile resistance |
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| H02P 9/24 | UGR2 | | . . | due to variation of make-to-break ratio of intermittently-operating contacts, e.g. using Tirrill regulator |
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| H02P 9/26 | UGR2 | | . . | using discharge tubes or semiconductor devices (H02P 9/34 takes precedence) [2] |
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| H02P 9/28 | UGR3 | | . . . | using discharge tubes |
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| H02P 9/30 | UGR3 | | . . . | using semiconductor devices |
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| H02P 9/32 | UGR2 | | . . | using magnetic devices with controllable degree of saturation (H02P 9/34 takes precedence) [2] |
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| H02P 9/34 | UGR2 | | . . | using magnetic devices with controllable degree of saturation in combination with controlled discharge tube or controlled semiconductor device |
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| H02P 9/36 | UGR2 | | . . | using armature-reaction-excited machines |
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| H02P 9/38 | UGR2 | | . . | Self-excitation by current derived from rectification of both output voltage and output current of generator |
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| H02P 9/40 | UGR1 | | . | by variation of reluctance of magnetic circuit of generator |
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| H02P 9/42 | UGR1 | | . | to obtain desired frequency without varying speed of the generator |
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| H02P 9/44 | UGR1 | | . | Control of frequency and voltage in predetermined relation, e.g. constant ratio |
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| H02P 9/46 | UGR1 | | . | Control of asynchronous generator by variation of capacitor |
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| H02P 9/48 | UGR1 | | . | Arrangements for obtaining a constant output value at varying speed of the generator, e.g. on vehicle (H02P 9/04 to H02P 9/46 take precedence) [3] |
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| H02P 11/00 | HGR | Arrangements for controlling dynamo-electric converters (starting H02P 1/00; stopping or slowing H02P 3/00; feeding a network in conjunction with a generator or another converter H02J) [4] |
| H02P 11/04 | UGR1 | | . | for controlling dynamo-electric converters having a dc output |
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| H02P 11/06 | UGR1 | | . | for controlling dynamo-electric converters having an ac output |
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| H02P 13/00 | HGR | Arrangements for controlling transformers, reactors or choke coils, for the purpose of obtaining a desired output (regulation systems using transformers, reactors or choke coils G05F; transformers H01F; feeding a network in conjunction with a generator or a converter H02J; control or regulation of converters H02M) [4] |
| H02P 13/06 | UGR1 | | . | by tap-changing; by rearranging interconnections of windings |
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| H02P 13/08 | UGR1 | | . | by sliding current collector along winding |
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| H02P 13/10 | UGR1 | | . | by moving core, coil winding, or shield, e.g. by induction regulator |
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| H02P 13/12 | UGR1 | | . | by varying magnetic bias |
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| H02P 15/00 | HGR | Arrangements for controlling dynamo-electric brakes or clutches (controlling speed of dynamo-electric motors by means of a separate brake H02P 5/00 , H02P 7/00) |
| H02P 15/02 | UGR1 | | . | Conjoint control of brakes and clutches [3] |
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| H02P 17/00 | HGR | Arrangements for controlling dynamo-electric gears [3] |
| H02P 19/00 | HGR | Arrangements according to more than one of groups H02P 1/00 , H02P 3/00 , H02P 5/00 or H02P 7/00 [5] |
| H02P 19/02 | UGR1 | | . | Providing protection against overload without automatic interruption of supply (emergency protective circuit arrangements with automatic interruption of supply H02H 7/08 , without disconnection, in general H02H 9/02) [6] |
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| H02P 21/00 | HGR | Arrangements for control or regulation of electric motors by control of field orientation; Vector control [6] |