DE1613887C - Electronic three-phase power switch - Google Patents

Description

two control voltages when two phases are interchanged as a result of one with the phase interchange effective change in the firing angle of the rectifier circuit arrangement working with the thyristors reversed in polarity, so that then a blocking auxiliary voltage via the control transistor is available at the switching transistor. The ignition angle shift of the thyristors in the event of a change the phase position is achieved by connecting

Ignition transformer Tr 3 lying auxiliary thyristor pair St 9, SiIO and the additional secondary windings of the ignition transformer Tr 3 are connected to the control circuit of the auxiliary thyristors Si 11, style in the primary circuit of the ignition transformer Tr 4.

The control transformer TrI , which is connected to the conductors S, mp on the primary side, ignites the auxiliary thyristors alternately after the switching contact Sch has been closed in a constant sequence of the mains frequency

Ignition voltages derived from the three-phase network St 7 and St 8 of the controllable rectifier bridges can be achieved. . circuit arrangement. About this rectifier scarf-Further details of the invention are to processing arrangement of the ignition transformer Tr 2 hand of Fi g. 1 to 3 explained in more detail. In connected to the mains voltage (R, mp) on the primary side. The in Fig. 1 is a three-phase power switch with a conductor T arranged thyristor pair Λ5, St6 control device, the switching on and off 15 now through the network to the consumer, evaluating the criteria of several monitoring at the same time, the same way is used in the connection arrangements; line of the transformer Tr 3 supporting auxiliary Fig. 2 shows the circuit arrangement of the current thyristors Λ9, SiIO controlled to be conductive. This monitoring device. the voltage reaches between the conductors T and mp between the mains-side connections R, S, T 20 to the primary winding of the ignition transformer Tr 3. and the consumer-side terminals /? ', 5', T, of the thyristor pair Λ3, Si4 in the conductor S. Also with the three-phase mains switch, the anode-cathode are ignited and the conductor S to the consumer is connected by two anti-parallel thyristors. Arranged at the same time as the ignition of the thyristor SiI to St 6 . The center conductor pair 3 Si, Si 4 are mp about the additional secondary is carried out without interruption. The control winding of the transformer Tr 3, the auxiliary device for the thyristor pairs consists essentially of thyristors Sill and St 12 ignited, which the voltage from ignition transformers Tr 2, Tr 3 and Tr 4 voltage between the conductors S and mp to the primary with auxiliary thyristors Si 7 to Si 12. Lay the winding and unwinding of the ignition transformer Tr 4. This switching process of the electronic three-phase network supplies the ignition currents for the thyristor pair SiI, switch is initiated when the primary 30 Si2. With the connection of the associated lead winding of the first ignition transformer Tr 2 to Netz- tersi? the electronic three-phase mains switch has applied voltage or is switched off. The now fully switched through.
Switching on or off is carried out by means of an electrical die consisting of the control transformer TrI, the switching niche switching device, which consists of a control transistor Ts 1 and the rectifier bridge switching transformer TrI with a secondary-side arrangement Si7, Si8, GrI, Gr8 Switching transistor Ts 1 and one of the switching devices is for evaluating the criterion-controlled rectifier bridge circuit arrangements of one or more monitoring circuit arrangements that are required in the primary circuit of the first arrangement. The primary winding of the ignition transformer Tr 2 is arranged. In the current control transformer TrI , via the switching circuit of the primary windings, the ignition transformers 40 clock Sch low power to the mains voltage S-mp Tr 3 and Tr 4, each of which can be connected between a three-phase conductor. The control transformer has firing pulses for the auxiliary thyristors Si9, SiIO or Sill, St 12. The auxiliary thyristors Si7 and Si8 of the controllable ignition transformers, which are each assigned to a pair of thyristors - rectifier-bridge circuit arrangement, are connected to two separate secondary windings and the neutral conductor is switched on. each carry two secondary windings, the 45 men, which are alternately ignited via a diode and a resistor with the for each half-wave. The auxiliary thyristors are each in series grid-cathode path form the control circuit of each Thy- with the diode GrI or Gr 8 in the circuit of the priristor. Rectifier diodes GrI to Gr 6 die winding of the first ignition transformer Tr 2. The suppression of the undesired control electrodes of the auxiliary thyristors are each half-wave. The control transformer TrI, via which the switching process is initiated at a winding end or winding rise, is connected on the primary side to both secondary windings, while the conductor S is connected via a switching contact Sch to the other winding end jointly via the neutral conductor mp. The three ignition trans- emitter-collector path of the switching transistor Ts 1 formators Tr 2, Tr 3 and Tr 4, however, are each connected to the interconnected cathodes of the auxiliaries Si 7, Si 8, Si 9, SiIO and Sill, 55 thyristors are connected. In the normal operating St 12 between the conductors R, S and T and the oil line state, the switching transistor TSI mp conductor is connected. For the control of the two border states, so that the auxiliary thyristors St 7 and the last mentioned auxiliary thyristor pairs, the two Si 8 are ignited alternately. The two ignition transformers Tr 2 and Tr 3 have already been provided with the additional secondary voltages mentioned for the control transformer secondary windings. The ignition circuits Ent- 60 mators TrI at the same time also supply the hold- open, here too, each with a rectifier diode Gr 9 up to voltages for the switching transistor TsI. The two Gr 12, which are each connected in such a way that the anti-alternating voltages are alternately decoupled from Gr 14 by means of diodes Gr 13 and auxiliary thyristors connected in parallel. The base-emitter circuit of the switching the oppositely polarized half-waves ignited transistor TsI is designed so that the opening will be. The assignment of the ignition transformers and 65 alternating voltage half-waves as a criterion from one of the thyristor pairs is made in such a way that the additional secondary windings of the ignition transformer can be superimposed on the additional secondary windings of the ignition transformer Tr 2 with that in the primary circuit of the next. The terminals one for this purpose

Resistor R 1 inserted into the control circuit of the transistor, to which the monitoring circuit arrangements are connected, are identified by reference symbols c and d .

The control transformer TrI is equipped with a third secondary winding which supplies an auxiliary DC voltage for the monitoring circuit arrangements via a rectifier circuit arrangement at terminals labeled α and b.

The current monitoring device for the three-phase mains switch in FIG. 2 is conductively connected at the terminals labeled α to d with the terminals of the same name on the switching device in FIG. Current transformers Tr 5 to TrI are used to monitor the current in the three conductors. After reaching the response value adjustable by load resistors R 2 to R 4, an opening control voltage is applied to a transistor Ts2 through rectifier bridges Gr 15 to Gr 17 connected in parallel on the DC side via a Zener diode ZD 2. In the event of an overcurrent, the transistor Ts 2 ignites a thyristor St 13. The switching transistor TsI (FIG. 1) normally opened by the diodes Gr 13, Gr 14 now receives a reverse voltage to its control path via a Zener diode ZD 3. The auxiliary thyristor pair StT, St 8 (FIG. 1) is extinguished at the next zero crossing of the mains voltage and is not re-ignited. The electronic three-phase mains switch locks and a signal lamp SLl lights up. The thyristor St 13 ignited by overcurrent can only be extinguished by opening the switching contact Sch (FIG. 1).

In the event of a short circuit, fuses SiI, Si2, Si3 disconnect the circuits and protect the thyristors StI to St 6 from inadmissible overloads.

The arrangement of the transmitter TrI to Tr 4 results in a mutual dependency of the ignition pulses, whereby the ignition of the thyristors Λ1 to St 6 is interrupted if any phase voltage fails.

The phase sequence monitoring device shown in FIG. 3 is connected to the three-phase network via transformers Tr 8, Tr 9 and TrIO connected in a star connection. The phase sequence monitoring is triggered at the left of rotation of the three-phase system and prevents the closing of the switch contact Sch (Fig. 1) the ignition of the thyristors StI to St 6. The three transformers have secondary side except each having a main winding I, II and III, two additional control windings of the ignition voltages of thyristors St 14 to St 16. The main windings I to III are also arranged in a star connection, from which two independent control voltages of different sizes are taken via two independent rectifier circuit arrangements, the difference of which is effective in the base-emitter circuit of a transistor Ts 3. In normal operation, the differential voltage is polarized so that the emitter-collector path of the transistor Ts 3 is blocked. The two rectifier circuits on the transformer star circuit arrangement differ in that rectifier diodes Gr 18 to Gr 20 in one circuit arrangement and thyristors St 14 to St 16 in the other. The removed at the two rectifier circuits voltages f are voltage divider R5, R and R6, RS ^"v to the control circuit of the transistor Ts out. 3 the voltage dividers are dimensioned so that the on the thyristors St 14, STIs, St 16 at If there is no ignition angle shift (without phase control), the DC voltage obtained predominates over the other DC voltage and controls the transistor in the conductive state. This case occurs when two phases of the network are interchanged. A signal lamp SL 2 indicates the wrong direction of rotation. With the correct phase sequence, however, remains the transistor Ts 3 blocked because the ignition of the thyristors St 14 to 5/16 takes place later due to the switching of the control windings due to the counter-switching of the control windings and the counter-voltage generated by the rectifiers Gr 18 to Gr 20 predominates. The phase sequence is monitored in mobile or moving systems indispensable to keep the consumer informed operate in the same phase sequence. The three-phase mains switch works with any phase sequence. /

1 sheet of drawings

Claims (5)

Patent claims: 1. Electronic three-phase power switch with arranged in each three-phase line thyristors as switching elements, to each of which an ignition transformer is connected in such a way that the thyristors can be ignited synchronously with the mains frequency, characterized in that in the primary circuit of the first ignition transformer (Tr 2) a; Semi-controllable rectifier bridge circuit arrangement short-circuited on the DC side. (Auxiliary thyristors St 7, St 8; rectifier diodes Gr 7, Gr 8), for their auxiliary thyristors (StT, StS) a control transformer (TrI) connected to the mains on the primary side with two separate secondary windings for controlling the two auxiliary thyristors (StI, St 8 ) it is provided that the emitter-collector path of a switching transistor (TsI) is arranged in a control branch common to both auxiliary thyristors (St 7, Si8) and that the control path of the switching transistor (TjI) with a current and a phase sequence monitoring device in such a way is connected that the switching transistor (TsI) can be blocked in the event of overcurrent or incorrect phase sequence. 2. Electronic three-phase power switch according to claim 1, characterized in that the current monitoring device is assigned a control thyristor (St 13) such that a blocking auxiliary voltage to the control path of the switching transistor (TsI) can be switched through it in the event of an overcurrent. 3. Electronic three-phase power switch according to claim 1, characterized in that a control transistor (Ts 3) is assigned to the phase sequence monitoring device in such a way that a blocking auxiliary voltage can be switched through it to the control path of the switching transistor (TiI) in the event of an incorrect phase sequence. 4. Electronic three-phase power switch according to claim 3, characterized in that in the phase sequence monitoring device a transformer arrangement (7V8 to TrIO) and two independent rectifier circuit arrangements made of thyristors (5/14 to St 16) or of rectifier diodes (Gr 18 to Gr 20) are provided for the formation of two independent control voltages, in such a way that the voltage difference between the two control voltages when two phases are interchanged as a result of a change in the firing angle of the rectifier circuit arrangement working with the thyristors ^ / 14 to Λ16) which is effective with the phase interchange the polarity is reversed, so that a blocking auxiliary voltage is then available at the switching transistor (TiI) via the control transistor (T ^ 3). 5. Electronic three-phase power system according to claim 3 or 4, characterized in that Ute ignition angle shift of the thyristors (.SV14 to .SV16) when changing the phase sequence by mutually switching ignition voltages derived from the three-phase network ei / ielbar. The invention relates to an electronic three-phase power switch with each three-phase line arranged thyristors as switching elements, to each of which an ignition transformer in such a way is connected so that the thyristors can be triggered synchronously with the mains frequency. Such a circuit arrangement is known (US Pat. No. 3,343,038). The well-known formwork arrangement serves as protection against phase failure. ίο The control pulses for the thyristors are in a special control device generated. For each phase of the network that is connected to the three-phase switch to be connected to a load, must be synchronized with the mains frequency for switching through Firing pulses are supplied to the control electrode of each thyristor. The thyristors are deleted automatically with each zero crossing of the phase voltage. Opening the electronic Three-phase mains switch can thus be carried out by suppressing the ignition pulses. In order to also counteract consumers connected via an electronic three-phase power switch To be able to protect overcurrent and phase reversal, monitoring elements are required which are Overload block the electronic switch or, if two phases are reversed, ignite the Prevent thyristors. The invention is based on the object of a circuit arrangement of the type mentioned at the beginning Kind of monitoring the current and phase sequence of all three phases with as little effort as possible to enable by means of a control device at a central point. According to the invention this object is achieved in that in the primary circuit of the first ignition transformer a semi-controllable rectifier bridge circuit arrangement short-circuited on the DC side is arranged, for their auxiliary thyristors a primary side connected to the network control transformer provided with two separate secondary windings to control the two auxiliary thyristors is that also the emitter-collector path of a switching transistor in one of the two auxiliary thyristors common control branch is arranged and that the control path of the switching transistor with a Current and a phase sequence monitoring device is connected in such a way that the switching transistor can be blocked in the event of overcurrent or incorrect phase sequence. The switch-on process of the thyristors in the three-phase conductors can be reduced via a contact Switching capacity, which applies voltage to the control transformer, can be initiated. According to an advantageous further development of the invention a control thyristor is assigned to the current monitoring device, which is used in the event of an overcurrent a blocking auxiliary voltage can be switched to the control path of the switching transistor. Furthermore, the Phase sequence monitoring device assigned a control transistor, through which in the event of an incorrect phase sequence a blocking auxiliary voltage can be switched to the control path of the switching transistor. Are there a transformer arrangement of the phase sequence monitoring device and two independent rectifier circuit arrangements made of thyristors or from rectifier diodes for the formation of two independent control voltages assigned in such a way, that the voltage difference between the