SU688074A1 - Method and apparatus for determining phase for shunting converting bridge - Google Patents

Abstract

1t The method of determining the phase for shunting the converter converter — that of the valves of this phase with no switching commutators of overcurrent disturbances of the switching of the valves, consists in detecting the presence of minimum phase currents of the transformer around-^ MOTioi, compare the current currents of the phase currents sensors this winding with a current of a rectified bridge current sensor, characterized in that, in order to increase the reliability of the bridge protection in case of valve switching failures, the moment of decreasing the instantaneous value of the difference the indicated compared currents below the setpoint, fix the moment of the end of the next commutation disturbance over it, count the specified time interval from the specified time, during which they fix the simultaneous presence of the switching output signal2. The method pop. 1, which differs from the fact that for a bridge operating in the inverter mode, the shunting is performed on the advancing phase valves, for the bridge operating in the rectifying mode, on the valves) either of the two indicated Phase protection of the bridge and minimum currents only in two phases of the valve winding, choose one of them according to the combinations of the phases indicated and bridge the bridge through the valves of this phase. A device for performing phase detection for shunting and a converter bridge according to claim 1, comprising phase current sensor vents | The transformer windings and a bridge current sensor, the comparison element connected to the specified current sensors, phase current relay elements and a relay relay element connected respectively to the outputs of the sensor current currents and the reference element, • "protection block” I distinguish''.ees by the fact that it is equipped with a prohibition element, elements of coincidence, a step and a shaper of time intervals, and one of the inputs of the element запрет: prohibition and the inputs of two of the terminals are connected to the outputs of each of the relay elements of the phase currents ex coincidence elements, the other inputs of which are connected respectively with the output of the inhibit element, the output of the backup unit and the output of the time interval generator, the input of which is connected to the output of the relay element. (ЛСОi 00 00о ^ ^ 4U

Description

the output of the reference element, and the outputs of the coincidence elements are connected to the memory elements

"/ The invention relates to electrical engineering, in particular, to methods of protection in the event of disturbances in the switching of valves of educational bridges with semiconductor valves used the same as shunt devices. The method extends to both periodic and aperiodic (irregular) disturbances, accompanied by alternating intervals of normal commutation and direct burning by a valve of one phase. A known method for detecting one or several valves in which there was a misfire or direct breakdown, based on the identification of combinations of a number of signs indicating the type of cutting. certain vents According to this method, the phase currents exceed a certain direction by the rectified bridge current to the specified settings, record the duration and sequence of current flow in the phases, after which combinations of coincidence of all time signals are detected. For example, to determine the valve on which the switch-on skip occurred, the stored combination of phase currents of a certain direction (taking into account the fact that one of these tokhoes flowed for a long time more than 160 e. At the moment preceding the direct burning of the valves of one phase) with a combination corresponding to a specific sequence of flow of phase currents arising. when the conversion bridge is pulled in from the specified mode. The known method has a number of disadvantages, the main of which is the complexity due to the need to control a very large number of attributes. In addition, using the fact of increasing the half-wave duration of the phase current can lead to incorrect phase determination for bridge shunting, since such an increase can occur not only if the switching in the damaged bridge is disturbed, but also on undamaged bridges, for example, during operation current regulator rectifier during a breakdown of the switching on the inverter. ({The closest to the technical essence of this invention is a method for determining the phase with a damaged valve, using as a sign of damage On the other hand, simultaneous reduction or increase (or both of them) of different polarity currents in the two phases of the valve winding, which takes place at the beginning and end of the interval of direct valve burning in case of switching disturbances. This known method of protection of the converter bridge against switching disturbances is based on the principle pulse control (reacting organs - switching sensors produce pulses proportional to the derivative of currents) of pairwise combinations of different polarity phase currents of the converter. In the case of coincidence of pulses in any of the combinations, a signal is sent to trigger the protection and the phase in which the switching fault takes place is fixed. This method is carried out by a device containing sensors of phase currents of valve windings of a transformer and an overcurrent sensor of a bridge, a reference element connected to sensors of phase currents, relay elements of phase currents and a relay relay element connected respectively to the outputs of sensors of phase currents and the element of comparison. The known method has a number of fundamental flaws. One of them is the use of derived phase currents, taking into account the sign of the change in currents, which may be the source of the false operation of the device, performed according to the method, in normal DC transmission modes, since the fronts of the phase currents of the winding winding both at the moments of switching on and especially when the switching valves go out, they are distorted due to the application of the oscillatory components of the current. The indicated supply currents arise as if due to; the presence in the circuit of a real converter of numerous, damping R-C circuits, and at the expense of its own high-voltage equipment. For this reason, in the switching interval, the magnitudes and signs of the derived currents, of two normally commuting phases, can be sources of incorrect information for the device. In addition, simultaneous current oscillations in two phases of a valve winding are possible not only in modes with disturbed commutants but also in other emergency modes, for example, at overlaps in modes with large control angles, accompanied by periodic overcurrents in the iid pulses in two phases. Noah winding. Similar changes in the currents of the winding winding occur when imposing on the transfer current, and therefore on the phase currents, the oscillatory components of the current caused by disturbances in adjacent bridges or in the converter station. The known method of fixing the damaged phase is also insufficiently perfect in cases of violation of valve commutations, because it is valid only for a well-defined mode (rectifier, solid or inverter) and does not take into account the fact that during the operation of the regulators and rectifier The reader in the inverter mode (PID), as well as in reverse, the operation modes of the converters can vary widely and the nature of the combinations of pulse signals at the end of the interval of the direct combustion of the valves varies depending on the mode. The above mentioned drawbacks of the known method can lead either to an unjustified shutdown of a normally operating bridge (during false operation or to aggravation of accidents due to additional superheated effects on the valves, which are not calculated (in the case of incorrect determination of the damaged phase during overcurrent closures). either to the wrong definition of the damaged phase and consequently the phase of the bridge shunting through the working valves in case of switching failure, as a result of which the bridge valves will be subjected supercurrent effects when the shunting apparatus is turned on, which removes the bridge from operation. This can be either an undersupply of electricity or the equipment’s output from the bridge with the outage of the bridge due to the need for repairing the bridge. in case of valve switching failures. The goal is achieved by the fact that in the known method of determining the phase for shunting the converter bridge through the valves of this phase With non-accompanying overcurrents and violations of the switching of the valves, reveal the moment of reduction of the instantaneous value of the difference of the indicated compared currents below the setpoint, record the moment of the end of the next violation of the switching over it, count from the specified moment a specified period of time, during which the simultaneous presence of the output protection signal is detected bridge and minimum currents in only two phases of the valve winding, choose one of them according to the combinations of these phases and carry out the bridge bypass m l of this phase, in addition, for the bridge. operating in the inverter mode, the shunting is carried out on the advancing phase valves, and for the bridge operating in the rectifying mode, on the valves of either of the two specified phases. An apparatus for carrying out this method, comprising a sensor of phase currents of the valve windings of a transformer and a sensor of the rectified current of the bridge, a comparison element connected to said current sensors, relay currents and phase relays connected respectively to the outputs of the phase currents and a comparison element, protection unit is equipped with a prohibition element, coincidence elements, memory elements and a time interval generator, and to the outputs of each of the relay elements of phase currents at One of the inputs of the prohibition element is connected and the inputs of two of the three coincidence elements, the other inputs of which are connected respectively to the output of the prohibition element, the output of the protection unit and the output of the time interval generator, the input of which is connected to the output of the relay element, are included on the output of the comparison element, and the outputs of the matching elements are connected to the memory elements. Figures 1a and 2a show current diagrams in the phases of the transformer's valve windings during converter operation in inverter and rectifier modes, respectively, when valve B is ignited; FIGS. 16 and 26 depict diagrams of operation of the elements of the device performed by this method, respectively, in the inverter and rectifying modes when skipping the + + valve; Fig. 3 is a diagram of a device that implements a method for determining the phase in the event of commutation disturbances for bridging a converter bridge with semiconductor thyristor rio valves and working valves. The process of operating the pass by turning on the ventilator + B of the converter bridge, operating in the inverter mode, before the action of protection against commutation of disturbances (Fig. 1a) is considered. At time t, an impulse is applied to turn on the A-A valve of the intact half of the bridge, after which the bridge enters the direct, burned phase A valve, at time t, after the impulse is turned on, the B is turned on, the bridge goes out of this mode and in phases A and B currents + A and -B (AB) appear, and at time ta, the direct burning mode ends and the phase currents again become equal to the rectified current. After this, the combination of currents will exist in the inverter mode for a period of 120 e. hail. In order to unambiguously determine the faulty phase, and therefore, for the correct choice of ventilates of one phase for shunting the mout, a certain combination of phase currents is recorded exactly at that interval after the bridge leaves the right-sided mode, valves of one phase can be switched. At time t, control pulses are removed and pulses are applied to phase A valves, since this leads to the most rapid bridge shunting. In moment t, the switch from valve -B to valve -A ends and the bridge is in single-phase mode. The process of operation in the rectification mode is discussed (Fig. 2a). At time t, the bridge enters the direct combustion mode of the phase A valves. At time t, the mode leaves this mode and currents + C and -A (CA) appear in phases C and A. Such a combination of phase currents will exist in a step-by-step mode after leveling the phase and rectified currents for 60 e.h. Thus, in order to correctly determine the valves of one phase, intended for shunting the bridge, for the rectifier and the inverter, it is necessary to fix the combinations of phase currents through which the bridge leaves the direct burning mode of the valves of one sec) at the shortest time interval, t. e. the interval defined by the process on the rectifier. At time 13, control pulses are removed and pulses are applied to shunt the bridge through phase A valves. At time t, the switching from valve + C ends. Valve + A ends and the bridge is shunted by phase A valves. On a rectifier, over the whole range of the control angle, the conditions of the 1P1 switch are such that the supply of pulses for shunting the bridge and through the phase C valves will lead to a similar result. The device (FIG. 3) for carrying out the method of determining the phase for shunting the converter bridge 1, operating in reverse or only inverter mode, on the working valves of one phase for switching disturbances, contains sensors 2 phase currents of the transformer-3 valve winding and (. Sensor 4 the current of the bridge current is an element comparing the currents 5 of said sensors, relay elements of phase currents 6 with a minimum setting in the circuits of sensors 2 and a relay element 7 at the output of the element of comparison 5 that responds to exceeding ohm phase currents. Each of the outputs of the elements of the phase currents 6 is connected to the inputs of two of the three elements of the match 8-10 in such a way as to obtain the entire combination of two phase currents (i.e. AV. AC, VS). To the other inputs of these elements matches are connected: the output 96 of the protection block 11 against commutation disturbances and the output of prohibit element 12 in the presence of currents in all three phases (for example, when switching in the converter); the output of the time interval generator 13, the input of which is connected to the output of the relay element 7. Outputs match items connected to the inputs of the memory elements 14–16, which form the output signals on the bypass of the converter bridge through the working valves of the selected phase with simultaneous removal of the working pulses of the valves. For the device in FIG. 3 of a conversion bridge intended for operation in reversible mode or only in inverter mode, the indicated memory elements form a signal for switching on advanced phase valves from a fixed combination of phase currents. For the device intended for operation of the converter in the terminal mode, the memory elements can form signals to turn on the valves of either of the two fixed phases. The operation of the device for violations. switching in the inverter mode, see the diagram of the output signals of the device elements (Fig. 16). When skipping the inclusion of the valve + B, we have alternations of the modes of direct combustion of the valves of phase A and the presence of different current durations in the phases with a slight increase in the rectified current. When the input voltage is in the direct combustion of the valves of one phase, the output of the comparison element 5 appears unbalance of the current of the bridge and rectified phase currents, and when this signal exceeds a certain setpoint, element 7 is triggered. Upon completion of the specified mode, simultaneously in two phases the valve winding of the transformer is currents (sensor 2), when they reach a certain minimum setpoint at the output of element 6, signals appear that correspond to half-waves of currents of certain phases (for example, phases A and B), the unbalance signal (output 5) disappears, 7 and at the same time at the output of the former 13 appears. a short signal with a duration of 1-2 ms, allowing the operation of the elements to coincide each time after aligning the currents of sensors 2 and 4 at the output of the bridge from the mode of direct combustion of valves of one phase. At this point, the protection unit 11 against switching failure should operate, the dwell time of which is determined by a certain tujjy J value and if there are no currents in all three phases of the winding winding (out.12), one coincidence element is assembled. The output of the coincidence element 8 triggers the memory element 14, as a result of which long pulses are emitted to shunt the converter bridge through the advanced phase valves (e.g., A) and control pulses are removed. The operation of the device in the converter converter mode (Fig. 26) proceeds as above, except that the bridge is pulled from the direct combustion mode through the valves of other phases (for example, + C and -A), i.e. compared to the inverter mode, the phase combination, and therefore another matching element 10 and the memory element 16 emit a signal for bridge shunting via phase C valves. Thanks to the use of the proposed method of phase determination for shunting the converter bridge From a shunt valve in case of valve commutation disturbances, a fundamentally new possibility of detecting the most optimal phase, through which valves correctly and quickly (with the least number of commutations) a shunting (converter, which prevents additional overcurrent effects on the valves when the shunt apparatus is turned on, output the bridge of the work. The economic effect of using the proposed invention is to reduce the amount, cost and time to repair the equipment, and kzhe in reducing the undershoot of electricity due to its simple.

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Claims (4)

1. The method of determining the phase for shunting the converter bridge through the valves of this phase in case of non-overcurrent violations of the switching of the valves, in that the presence of minimum phase currents of the valve winding of the transformer is recorded, the rectified currents of the phase currents • sensors of this winding are compared with the sensor current of the bridge rectified current, which means that, in order to increase the reliability of bridge protection at violations of switching of valves, they reveal the moment of reducing the instantaneous value of the difference between the indicated compared currents below the setpoint, fix the moment of the end of the next violation of the switching over it, count out from the specified moment the given mezhutok time during which fix the simultaneous presence of a circuit output signal 2 protection of the bridge and minimum currents only in two phases of the valve winding, choose one of them by the combinations of these phases and carry out the bridge shunting through the valves of this phase. 2. Method pop.1, characterized in that for the bridge operating in the inverter mode, the shunting is performed on the advancing phase valves, for the bridge operating in the rectifying mode, on the valves of either of the two specified phases. * »· 3. A device for phase detection for shunting r, $ converter bridge according to claim 1, containing phase current sensors of ventilators <tangles of transformers and bridge rectified current sensor, a comparison element connected to said current sensors, relay elements of phase currents and comparing relay element connected respectively to the outputs of the phase currents and comparing the sensor element, ^g "protection unit, characterized in that it is provided with something element prohibition matching elements, memory and temporary shaper int torn, wherein ^the outputs of each of the relay "phase currents elements coupled one of the inputs of the <prohibition and inputs two of the three matching elements, the other inputs of which are respectively connected to the output element prohibition output protection unit and the output of the time slots, an input coupled to output relay element SC "688074 3 688074 four included at the output of the comparison element, and the outputs of the coincidence elements are connected to the memory elements </