HU182888B - Static frequency converter with direct voltage inverter input - Google Patents

Abstract

A rectifier feeds an inverter having main thyristors T1-T4 in a bridge circuit. Two trains of pulses gate bursts of oscillation from an oscillator to five pairs of thyristors in opposite arms of the bridge alternately. Each arm of the bridge is connected to a pair of anti-parallel connected quenching thyristors Ta connected to a quenching capacitor Cs. The quenching thyristors are turned on respectively by pulses derived by a differentiating circuit and a monostable circuit from the leading and trailing edges of the pulses which turn on the main thyristors in a pattern such that each main thyristor is quenched at the correct time. A protective circuit is provided to short out the d.c. voltage between the rectifier and the inverter when a short circuit is sensed (Figure 1 not shown). <IMAGE>

Description

are connected, the output of which is connected to the primary windings of the pulse transformers, while the secondary windings of said said pulse transformers are connected to the control electrodes of the main thyristors.

FIELD OF THE INVENTION The present invention relates to a static frequency converter with a constant dc inverter input for supplying a variable frequency primary power supply to a specific frequency electrical power supply which serves as a power source for electric heating of trains or as auxiliary power for other auxiliary equipment.

Static frequency converters have already been used for electric heating of trains. These converters were powered by a DC circuit, and the converter was protected by an electronic device. The disadvantage of this solution is that the construction is very complex and at the same time extremely expensive.

Our aim is to eliminate these disadvantages. The static frequency converter of the present invention, which has a constant-voltage inverter input voltage, eliminates the disadvantages of known static frequency converters by performing a single-frequency thyristor frequency generator impinging on the pulses needed to control the main thyristors and the load current. These pulses are divided into two parts by a first and a second frequency divider circuit. The distributed pulses are integrated with an integrating circuit whose output produces triangular signals. These signals are applied to a Schmitt trigger along with a variable voltage whose voltage is adjusted by a potentiometer. The pulses appearing at the output of the Schmitt trigger and the pulses of the dividing circuit are applied to two gate circuits, the output of which displays time-shifted pulses, which lead to differentiating and inverter circuits. The pulses of the differentiating circuits are applied to a monostable tilt circuit whose output delivers pulses of defined forehead width. These pulses are applied via pulse amplifiers to the primary winding of a transformer. The control pulses of the chopping thyristor appear on the secondary windings of the pulse transformer. The control pulses of the master thyristor are obtained from an unstable circuit. The pulses are then applied through a gate circuit to a pulse amplifier that is loaded on the primary windings of a pulse transformer. The secondary windings of the transformer supply the control pulses of the master thyristor. The converter has a startup delay to prevent a short circuit during startup. This delay is accomplished by a start delay circuit when the power supply to the electronic circuits is turned on. It blocks the pulse of the main thyristor through a gate circuit. This gate circuit remains blocked until a half-period trigger pulse is generated which controls the gate circuit when the delay time has ended. Therefore, the pulses of both the master thyristor and the auxiliary thyristor are simultaneously controlled. The latter charge the chopper capacitor. In this way, the energy required to extinguish the thyristor is provided at the end of the power-on period. The converter also has a stop2 circuit that prevents the inverter from short-circuiting, in which case the inverter is disconnected from the power supply. The inverter also has a master thyristor control pulse deactivation circuit, which is activated when the disable command is received or when the internal short circuit protection circuit is activated. The protective current, which continuously monitors the output voltage, normally interrupts power at the end of the period when the stop pulse command signal arrives. As a result, there is no current flowing in the next period and the inverter thyristor is disabled. In the case of an internal short circuit or a short circuit to the load circuit (which is both a short-circuit for the power supply), the electronic circuit breaker is powered by the protection circuit). The inverter is protected against a possible internal short circuit or a so-called external short circuit under load by a short-circuit protection device whose contact is connected to the DC intermediate circuit so that it is connected between the center branch of the filter coil and one or other output terminals of the rectifier.

An exemplary embodiment of the present invention will be described in more detail by reference to the drawing. In the drawing it is

Fig. 1 is a block diagram illustrating a static frequency converter according to the invention with a constant dc inverter input;

Fig. 2 is a schematic diagram of the inverter, a

Figure 3 is a block diagram of a protective and control electronic circuit, a

Figure 4 is a pulse diagram of the circuit.

The static frequency converter of the present invention comprises an intermediate constant dc voltage circuit. The circuit includes a three-phase diode rectifier 1, a thyristor-controlled inverter 2, a power switch 3, a load current switch 4, a current transformer 5, a protective circuit transformer 6, a transformer 7, a controller and an automatic unit 9, a 9 a capacitor, a short-circuit protective circuit 11, a load limiting coil 12, a recuperator diode 13, a limiting resistor 14, a capacitor 15, and a circuit for detecting a change in voltage polarity 16.

The static frequency converter is powered by an AC synchronous generator for the heating system, which is a three-phase system. The frequency of the generator depends on the speed of the drive diesel engine and its voltage is constant. At the input of the static frequency converter is a power supply three-phase switch 3.

The output of the inverter 1 of the converter is constant voltage, regardless of the frequency of the generator. An LC member consisting of 9 coils and 10 capacitors ensures proper filtration.

In order to prevent overvoltage of the filter capacitor, the RC member consisting of diode 13, resistor 14 and capacitor 15 provides protection. In the event of a fault in the inverter or the load circuit, the short circuit is energized at protective current 11 and shuts off the voltage at the inverter terminals for four ms,

-2182 888 shuts down the power supply to the generator and shuts down the static frequency converter.

The inverter 2 is powered by a DC power supply. The output of the inverter 2 displays a single-phase AC rectangular voltage and a constant frequency current. The electronic control unit of the control unit and the automatic unit generates the pulses necessary for the operation of the inverter according to the selected frequency. The control and automatic unit 8 receives information about the voltage of the transformer 7 and the output current of the transformer 6, thereby providing protection. In addition, the control and automatic unit 8 receives voltage signal information from the voltage on the circuit, if any, inside or outside the external short circuit, the voltage of the intermediate voltage intermediate circuit providing internal short circuit protection of the inverter. In addition, the control and automatic unit 8 switches the converter 3 on and off when the static frequency converter is switched on or off or when an error occurs. The output current of the inverter is measured by the transformer of the current meter.

In one embodiment of the static frequency converter according to the invention, the inverter current control is controlled by auxiliary current chopper thyristors, in which case the quenching capacitor is disconnected.

Fig. 2 illustrates the main thyristors Tj, T ₂ , T ₃ , T ₄ which can be terminated by the damping voltage applied to their control inputs when in the conductive state. The load of the inverter is connected to the middle corners of the bridge consisting of main thyristors Tj, T ₂ , T ₃ , T ₄ . Since Tj, T ₄ főtirisztorok collectively switched off, this fact is determined that the load current does not flow in a half period of time. At the moment when the photoresistors T ₁ , T ₄ turn off, the capacitors C _s j, C _s 2, Cs 3> C ≤ 4 are charged by the auxiliary resistors T _a j, T 1, which receive control pulses. The capacitors are charged by an oscillator circuit consisting of the following switching elements: T _t main thyristor, T _a auxiliary thyristor, L _s i coil, C _s i capacitor, and T ₄ main thyristor, Ta ₂ auxiliary thyristor, L g coil, C _s 2 capacitor. The function of capacitors C _s i, Cs4 is to keep the main thyristors T ,, T ₄ at the moment when the auxiliary thyristors T _a 3, T _a4 turn off. At this point, the discharge oscillation process of said capacitors is initiated, whereby the main thyristors T _t , T ₄ continue to conduct. The capacitor discharge current is closed by circuits similar to those mentioned above. During the switching of the oscillator circuit, the load current is provided. The discharge peak is led by antiparallel Di, D ₂ diodes connected to thyristors. Once the coupling is completed, optionally the Ti ', T ₄ főtirisztorokra blocking voltage drops, T _2, T ₃ főtirisztorok turned off and simultaneously _the four segédtirisztor főtirisztor of T ₃ and T is switched off. The load is taken over by the main thyristors T ₂ , T ₃ in the other half period. Charging of the chipping capacitors is then ensured by the proper polarity of a circuit similar to that described above. Operation of the chopping circuit is provided by the control of the main thyristors T ₂ , T ₃ .

As the reactive load created, that is, when Ti, T ₄ főtirisztorok tearing, the reactive load current fed to the recuperative D], _D2 diodes, that these diodes conduct the current over time depending on the size of terheló'áram.

Figure 3 illustrates the switching of the inverter electronic control. This circuit ensures that the main thyristors are switched at the desired frequency.

The operating frequency of the inverter is provided by a clock generator which is shown in FIG. The rectangular voltage shown in FIG. The pulses generated by the generator 17 are divided into two parts of the trigger circuit 18, and the pulses generated in FIG. Figure 1B creates a signal sequence with a fill factor of 1/2.

The pulses generated by the trigger circuit 18 are shown by the bistable trigger circuit 19 in FIG. 4c. half turns into impulses. The rectangular pulses appearing at the output of the trigger circuit 18 are integrated by an integrating circuit 20 and produce a triangular voltage, which is shown in FIG. is shown. This triangular voltage is applied to the input of the comparator 21 formed by the Schmitt trigger, together with the variable signal taken from the potentiometer 22. At the output of the comparator 21, the pulses appear with a pulse break, where the length of the pulse break is determined by the level of the continuous voltage applied to the potentiometer 22 (see Fig. 4e).

These pulses, along with the signals from the bistable trigger circuit 19, are applied to the gate circuits 23 and 24. The outputs of the gate circuits 23 and 24 (these circuits are coincidence circuits) are shown in FIG. and 4g. The pulses of the form shown in FIGS. 1A to 4B are obtained, having a half-width of the front width and a frequency equal to the operating frequency of the inverter.

The semiconductor pulses are differentiated by the differentiating circuits 25 and 26 so that they are short differentiated at the start of the semiconductor pulses; : we get pulses as shown in 4h. and 4j. Figures.

The same half-period pulses are reversed by the blocking circuits 27 and 28 and then differentiated by the differentiation circuits 29 and 30. At the output of the differentiating circuits, short pulses are obtained at the ends of the half-period pulses, as shown in FIG. and 4k. .

The differentiated pulses obtained as described above are applied to the monostable circuits 31, 32, 33 and 34, which generate pulses with a constant long signal arc. These pulses are amplified by amplifiers 35, 36, 37 and 38. These amplifiers feed the primary windings of the pulse transformers 39,40,41 and 42. The secondary windings of these transformers supply control voltages chopping thyristors.

The Schmitt triggers 43 and 44 are fed with pulses of 500 Hz. These pulses, generated by the unstable tilt circuit 45, are applied to Schmitt triggers 43 and 44, the outputs of which have a signal until the end of the semiconductor signals, as shown in FIGS. 41 and 4m. .

The pulses at the outputs of the Schmitt triggers 43 and 44 are of opposite phase. These pulses are applied to pulse amplifiers 46, 47, 48 and 49, which supply pulse transformers 50, 51, 52, and 53. Two of the secondary windings 50 and 51 of the pulse transformers 50 and 51 are interconnected, and these secondary windings control the converter switching T! and T ₄ main thyristors. The pulse width of the converter is the same as the current of the main thyristors.

The secondary windings of the impulse transformers 52 and 53 are connected by two and the main T ₂ , T ₃

-3182 888 are controlled by thyristors. The width of the control pulses is the same as the thyristor current conducting time.

The control pulses of the Tj, T ₂ , T _3, and T ₄ photoconductors can be suppressed by the corresponding polarity signals of a bistable multivibrator 54 controlled by a logic circuit 55.

The logic circuit 55 is controlled at its input and thus determines the disabling of the master pulse control pulses to which the following circuit is applied;

Upon power-up, a power-on delay is provided by the delay circuit 56, which controls the gate circuit 57 and, from the moment the power supply is turned on, disables the pulses for the electronic circuits until a half-time delay has elapsed. In this way, once the electronic circuits are turned on, after the said half-time, the pulses controlling the main thyristors (see Fig. 4f) and the pulses filling the chopping capacitors (see Fig. 4h) are simultaneously triggered. The input current of the resistor divider circuit 16 shown in FIG. 1 is applied to the input of the internal short-circuit current 58 when an internal short circuit occurs which provides a control signal to the logic circuit 55. The protective circuit 59 limiting the output voltage of the converter is controlled by the signal of the transformer 7 shown in Figure 1, so that the value of the voltage at the output of the converter is within the permissible limits. If the voltage exceeds the allowed limit, it is controlled by the logic circuit 55 of the protective circuit 59 when, and inhibits T ,, T _2, T ₃ and T ₄ főtirisztorok vezérló'impulzusait and 60 through the actuation circuit approx. breaks the switch 3 for three seconds. The stop button 61 can be used to turn off the converter as desired. The pulse to the bistable multivibrator 54 through the logic circuit 55 is then inhibited, and the actuator 60 is actuated, which disconnects the switch 3. The input current is connected to the output of the inverter 2 when the protective current 62 provides continuous protection of the converter output voltage. If there is a difference between a negative and a positive change in the output voltage that exceeds a predetermined value, a protective signal is applied to the protective current 62 for a certain time, thereby inhibiting the control pulses of the main thyristors and providing a command signal to turn off the converter. The external short-circuit protection of the converter is provided by an external short-circuit protection circuit 63 which is controlled by the transformer 6 shown in FIG. If the load current exceeds the maximum allowable value, the voltage signal of circuit 63 is

The short-circuit shown in FIG. 1 activates the control circuit 64 and the display circuit 65 of the protective current 11.

The operating frequency of the inverter 2 can be set by the frequency switch 66. If the switch is changed to 16 2/3 Hz while the inverter is operating, then it is certain to go to position 0 and that the impulse suppression and the converter shutdown will be performed by the logic circuit 55. The operating frequency is changed when the converter is not working.

The static frequency converter of the present invention provides the following advantages;

The equipment is highly reliable and provides adequate protection in all cases;

The equipment can be realized at a relatively low cost.

Claims (5)

1. A static frequency converter with a constant DC input voltage, characterized in that both the main thistors (Ti, T ₂ , T ₃ , T ₄ ) of the inverter (2) and the auxiliary thyristors (T _a j, T _a 2, T _a 3, T _{of the} control organ 4) generating a pulse generator (17) is formed, which is connected to a generating pulses generator (17) signals dividing the first frequency divider trigger circuit (18) and in series connected second frequency divider flip triggeráramkörhöz (19) comprises two half-symbol ; further, the first frequency divider trigger circuit (18) is connected to an integrating circuit (20) for generating triangular signals, the output of which is connected to one input of a comparator (21) and the slip contact (22) of a voltage control potentiometer to the other input of the comparator (21). ; and that the output of the comparator (21) and the bistable trigger circuit (19) are connected to two gate circuits (23, 24) that gate the time-shifted signal, while the latter are connected to differentiation circuits (25, 26) and prohibition circuits (27, 28). while the outputs of these circuits are coupled to further differentiating circuits (29, 30); and that the differentiating circuits and the further differentiating circuits (25, 29, 26, 30) are connected to monostable circuits (31, 32, 33, 34) whose output is connected to the primary windings of the impulse transducers (39, 40, 41, 42) on amplifiers (39). 35, 36, 37, 38); further, that the secondary windings of said pulse transformers (39, 40, 41, 42) are connected to the control inputs of the auxiliary thyristors (T _a i · T _a 2, T _a 3, T _a 4) that power off the main thyristors; further, the control unit of the main thyristors (Τι, T ₂ , T ₃ , T ₄ ) is constituted by a bistable multivibrator (54) connected to Schmitt triggers (43, 44) and the Scmitt triggers (43, 44) are gate circuits (43). They are also connected to the outputs 23, 24), while the outputs of the Schmitt triggers (43, 44) are connected to pulse amplifiers (46,47,48,49) whose outputs are connected to the primary windings of impulse transformers (50, 51, 52, 53), The secondary windings (50,51, 52, 53) are connected to the control electrodes of the main thyristors (Τι, T ₂ , T ₃ , T ₄ ). 2. static frequency converter according to claim 1, embodiment, wherein it provides inhibition of the inverter (2) an internal short-circuit time delay circuit (56) comprising a gate circuit (57) via the főtirisztorok (T [T _2, T _3, T ₄ ) is connected to a bistable multivibrator (54) which is a control device. An embodiment of a static frequency converter according to claim 1 or 2, characterized in that the control pulses of the main thyristors (Τι, T ₂ , T ₃ , T ₄ ) are blocked (27, 28) or an internal short-circuit protection circuit (58). ) or a non-continuous component protection circuit (62). An embodiment of a static frequency converter according to claim 1, characterized in that the inverter (2) is provided with additional capacitors to protect against short circuits of the inverter or a short circuit to the load and the additional capacitors are in the control and automatic unit (8) of the electronic protective circuits. placed. -4182 888 5. An embodiment of a static frequency converter according to any one of claims 1 to 5, characterized in that the inverter (2) has a short-circuit protection circuit (11) for short-circuit protection of the inverter and short-circuit contact of one of the rectifier outputs 9 in the DC voltage circuit. ) is connected between the center junction and the other rectifier output.