SU1131002A1 - Device for starting synchronous electric machine - Google Patents

Abstract

A DEVICE FOR STARTING A SYNCHRONOUS MACHINE containing a thyristor converter with direct connection, the input of which is intended to be connected to the AC network, and the output to the winding of the synchronous machine core, the formers of the triac pulses of the specified converter, two sensors of the synchronous machine rotor , a direct current exciter, intended to be connected to the inductor of a synchronous machine, characterized in that, in order to improve the weight and size parameters by The set power of the converter, three AND matching elements, two HE elements, a unit for comparing the measured average current with a predetermined setpoint current, a difference converter of the compared currents into a unit amplitude signal, the outputs of the first and second coincidence elements, And are connected to the inputs of the corresponding shaper pulses of the cathode thyristors and anodic groups, some of their inputs are connected to the corresponding outputs of the rotor position sensor, and the other inputs of the first and second elements coincide And I connected to the output of the third element ow (L fall I, one input of which is connected via the first element NOT to the first, current core sensor, and the other input of the third matching element AND through the second element NOT to the output of the difference converter of the compared currents in a single amplitude signal connected in series with the specified cp block, whose input is connected to the second current sensor box.

Description

one

The invention relates to electrical engineering and can be used to start high-power synchronous motors and compensators from an industrial network of 50 Hz through a valve converter.

o Known device for starting

A synchronous motor containing a frequency converter, the output of which is connected to a synchronous motor, and the excitation winding is connected to the exciter, the frequency converter control system. When powered from an AC network, the converter is most often performed as a frequency converter with a direct link.

The use of such a converter with natural commutation is advisable in cases where the frequency at the output of the converter, i.e. engine frequency, significantly less than the frequency of the mains.

In other cases, frequency converter circuits with direct coupling with forced commutation or with an intermediate circuit of high-frequency alternating current are used, which allow to increase the frequency of the output of the converter, i.e. receive at the output an adjustable frequency from zero to 50 Hz with mains supply also with a frequency of 50 Hz L 13.

However, these circuits are complex and have a large installed capacity of additional switching devices.

The closest in technical essence to the present invention is a device for starting a synchronous machine, containing a thyristor converter with a direct connection, the input of which is intended to be connected to an AC network, and the output to the core winding of a synchronous machine, a thyristor trigger pulse driver rotor, core current sensors, a separate DC exciter, which is connected to the inductor of a synchronous machine, as well as a current control circuit 2.

A disadvantage of the known device is associated with the fact that the start-up of a synchronous machine (motor), when its load is used little, the power of the converter is commensurate with the limit of 10022

power of the synchronous machine, which is economically disadvantageous.

The purpose of the invention is to improve the mass and dimensional parameters by reducing the installed power of the converter 5.

This goal is achieved by the fact that a device for starting a synchronous machine, containing a thyristor converter with a direct connection, the input of which is intended to be connected to an AC network, and an output to the winding of the synchronous machine core, forms the thyristor trigger pulses of the specified converter, sensor the position of the rotor of the synchronous machine, two current sensors core, the exciter DC, pre0 assigned to connect to the inductor of the synchronous machine, introduced three elements match And, d VA element NOT, a unit comparing the measured average current with a given current

5 setpoints, the converter of the difference of the compared currents into a signal of unit amplitude, the outputs of the first and second elements of the matches And are connected to the inputs of the corresponding

The Q drivers of the cathode and anode unloading thyristor pulses, groups of one of their inputs are connected to the corresponding outputs of the rotor position sensor, and the other inputs of the first and second coincidence elements And are connected to the output of the third element And, one input of which is connected to the first current sensor core through the first element NOT, and the other input of the third element matches And through the second, the element NOT to the outputs of the converter of the difference of the compared currents into a signal of unit amplitude, successively interconnected with the indicated

 a comparison unit, the input of which is connected to the second current sensor box.

FIG. 1 shows a block diagram of a device for starting synchronous

Cars; in fig. 2 is a graph of the network voltage and current in the motor winding.

A device for starting a synchronous machine (motor) 1, contains a thyristor converter 2 frequencies with a direct connection - a cycloconverter. In this example, the converter is wired according to the zero scheme, respectively, the engine neutral is connected by a dotted line with the network neutral. Phase A of the converter is shown in the diagram, phases B and C are shown as blocks. The control system is depicted for phase A. The control system of phases B and C is fulfilled in a similar way. The motor inductor is connected to a separate driver 3. On the motor shaft, a 4 position sensor is installed, at the outputs of which positive potentials are created and maintained for a period of time while the pole of the corresponding polarity is in the pole phase division zone of the AC motor winding. The control system consists of thyristor tripping pulses 5 and 6, two current sensors 7 and 8, three AND 9-11 coincident elements, two HE elements 12 and 13, a converter 14 of the difference of the matching signals into a unit amplitude signal, comparison unit 15, In this, the inputs of the enable pulses 5 and 6 are connected to the outputs of the first and second circuits, the matches of 9 and 10, one inputs of which are connected to the outputs of the 4 position sensor, and the other inputs to the output of the third match element 11, one input of the third element AND 11 connected with lane With the current sensor 7, the core through the first element NO 13, and the other input through the second element 12, with the output of the converter 14, the difference of the compared current signals into a unit amplitude signal connected in series with the comparison unit 15, the output is connected to the second current sensor Cor 8. The device works as follows. During the start-up process, the current sensor 8 measures the average starting current of the motor. The magnitude of this current in comparison unit 15 is compared with a predetermined current value (starting current setting). At the output of this unit, a differential signal is produced, the value of which is equal to the difference between the actual and the specified starting current. This differential signal is applied to the specified converter 14 | which produces a inhibitory signal, the duration of which is directly proportional to the difference between the actual and the specified starting current. This prohibitory signal, through the element 12, is fed to the input of the matching element 11. At the same time, another current sensor 7 detects the presence of a motor current. In the presence of a motor current at the output of the sensor, a prohibitory signal is generated, which is removed when the motor current becomes equal to zero. This prohibitory signal through the element NOT 13 is applied to another input of the match element AND P. Thus, at the output of the match element AND 11, the signal occurs when the prohibition on both inputs of the match element 11 is removed. The presence of a signal at the output of the match And 1I means that the average starting current does not exceed a predetermined value and the instantaneous value of the motor current is zero. If there is a signal at the output of the coincidence element I 1I and depending on the position of the rotor and, accordingly, the signal of the position sensor at the output A1 and A2, one of the forcing pulses, forming the unlocking pulses, is started through the matching element 9 or the matching element 10 the cathode group thyristors, or the driver 6, which forms the enabling pulses; thyristor anode group. The firing pulses are generated with an uncovered delay in time (on the order of several ms) necessary to restore the thyristor's locking properties. At the output of the driver, a single trigger pulse is generated, which is applied to the valves of the thyristor switch. Depending on the position of the rotor, the trigger pulses are applied to the valves of the anodic or cathodic groups so that the polarity of the pulse current in the alternating current winding corresponds to the polarity of the pole, the axis of which is within the pole division of this winding. At the same time, the created impulse moments are always positive. When a single enable pulse is applied to the thyristors of the valve switch, that - opens. thyristor, the ayodic voltage on which is the highest (in bridge circuits there is also a thyristor, the cathode voltage of which is lowest), This 5 causes a single impulse of current to flow in the alternating current winding of the machine. - A torque pulse is generated from the interaction of this current with the excitation flow. . Due to the fact that the current pulse is generated by a variable mains voltage that passes through zero and changes polarity, the instantaneous value of the current pulse also inevitably after a time in the absence of a trigger signal becomes equal to zero. When the pulse current becomes equal to zero, the input element of the match I I1 (through the current presence channel | a resolving signal appears to feed the next trigger pulse. If the average starting current after the flow of current does not exceed the preset value, then another input of the element And 1 1 (a permissive signal also appears on the current measurement channel and the driver generates the next trigger pulse. If the average starting current exceeds a predetermined value, then the enable signal at the input of the element fall And I1 occurs with some delay. This leads to an increase in the pause between pulses and, consequently, a decrease in the current value. Thus, the valve switch operates in the natural switching mode, when the thyristor is locked in a natural way when the direct current coincides to zero. no unlocking signal. The diagram (Fig. 2) of the mains voltage and current in the motor winding when the valve switch is powered from a three-phase AC network. The zero diagram shows the voltage of the power supply network DC, U5, Uc and impulse current in the motor winding when the control of distinct corners Aube. at different phases of the triggering pulse supplied to the thyristors of the thyristor switch. As follows from the diagram, the current pulse starts from the moment of supplying the trigger pulse under the action of the voltage of the phase that has the highest positive value / fB in this case of phase A. The current pulse form 2, if the nature of the load is inductive, which practically takes place, has a sinusoidal shape a function whose maximum occurs at the time when the voltage function passes zero. With inductive load, the current pulse shape is symmetrical. The pulse duration, as follows from the diagram, is t 2 TT - 2 ° C, where A. is the angle (phase) of the trigger pulse relative to the voltage, which forms the current pulse, phase A). The pulse duration, depending on the phase of the trigger pulse, can be adjusted within a range of up to 30; at a frequency of 50 Hz, this corresponds to a pulse duration of 16.6 - 3.3 ms. The steering angles corresponding to these limit values are C ,,, 30 AND СХ. 0 ((Fig. 2S, i). The amplitude of the current pulse and, therefore, the average value of the starting current and torque can be adjusted accordingly. At control angles of (.30, the phase C thyristor is disconnected from the voltage DC J and the control angle should be counted from the initial phase of the voltage U (.. At the control angles of ° C 150, the thyristor of phase B is respectively unlocked from the voltage Uj. Thus, this device allows the use of a gate switch made according to the frequency converter circuit with direct connection to switching, for starting synchronous machines, the nominal frequency of which is equal to f or equivalent to the frequency of the networks with the ability to regulate the starting current when powered from an unregulated network with a frequency of 50 Hz. This provides an improvement in the mass-dimensional parameters of the entire device, since double energy conversion in the rectifier is eliminated and inverter, as well as artificial switching devices, power, inductive and capacitive elements.

Claims (1)

DEVICE FOR STARTING A SYNCHRONOUS MACHINE, containing a thyristor converter with direct connection, the input of which is intended to be connected to an alternating current network, and the output is to the armature winding of a synchronous machine, the triggering pulses of thyristors of the specified converter, the position sensor of the synchronous machine rotor, two of the armature current sensor, a direct current exciter designed to be connected to the inductor of a synchronous machine, characterized in that, in order to improve the overall dimensions by reduced The installed power of the converter, three coincidence elements AND, two elements NOT, a unit for comparing the measured average current with a given setpoint current, a converter for the difference of the compared currents to a unit amplitude signal, the outputs of the first and second coincidence elements AND are connected to the inputs of the corresponding formers of the triggering pulses of the cathode thyristors and anode groups, some of their inputs are connected to the corresponding outputs of the rotor position sensor, and other inputs of the first and second coincidence elements AND are connected to the output of the third element of coincidence AND, one input of which is connected through the first element NOT to the first sensor of the armature current, and the other input of the third element of coincidence AND through the second element NOT - with the output of the converter of the difference of the compared currents into a signal of unit amplitude connected in series with the indicated unit the input which is connected to the second armature current sensor. „SU“ .1131002 power of the synchronous machine, which is economically disadvantageous. The purpose of the invention is the improvement of overall dimensions by reducing the installed capacity