RU2392654C2 - Device for automatic control over bridge thyristor rectifier - Google Patents

Abstract

FIELD: measurement equipment. ^ SUBSTANCE: invention relates to electrical measurement equipment and may be used for contactless automated control of the value of half-period average voltage of a bridge thyristor rectifier when situations occur in the rectification circuit that are connected with thyristor rupture or disruption. the device contains a mictoinductive solenoid-concentrate represented by several coils of the thyristor rectifier feed wireway. Inside the solenoid a sensor is placed whose output is connected to the signal amplifier. The amplifier output is connected to the input of a band filter set to frequency 2ë where ë is frequency of the voltage feeding the bridge thyristror rectifier. The band filter output is connected to the inputs of the logical unit comparators having different response levels. To the lower response level comparator output inputs of logical circuits 2AND-NO and 2AND of the logical unit. Connected to the second input of logical circuit 2AND-NO are the higher response level comparator output and the second input of the thyristor rectifier control system. Output of logical circuit 2AND-NO is connected to the second input of logical circuit 2AND to the output whereof the first input of the thyristor rectifier control system is connected. ^ EFFECT: improved reliability of operation. ^ 3 dwg

Description

The present invention relates to electrical engineering and can be used for non-contact automated control of the average rectified voltage of a thyristor bridge rectifier in the event of a fault in the rectifier circuit associated with an “open” or “breakdown” of the thyristors.

A device for monitoring semiconductor devices that are part of the rectifier, connected to a controlled semiconductor device using probes, which monitors the operating modes and determines the health of the device (its technical condition) by evaluating the response of the semiconductor device to the stimulating effect in the form of rectangular pulses following from special generator [Markin V.V. et al. Technical Diagnostics of Valve Converters / V.V. Markin, V.N. Mironov, S.G. Obukhov. - M .: Energoatomizdat. 1985].

When using this device, it is necessary to provide a contact connection of the controlling device with the control object - a semiconductor device.

A device for contactless monitoring of semiconductor elements of single-phase and three-phase bridge rectifiers [A.G. Sukiyazov et al. Device for non-contact monitoring of semiconductor elements of single-phase and three-phase bridge rectifiers. Patent for PM No. 66820, 2007]. The device contains a magnetic field sensor located near the rectifier transformer, a sensor signal amplifier and a bandpass filter tuned to a frequency of 2ω (ω is the frequency of the supply voltage rectifier), the output of which is connected to the logical part of the device, which, depending on the magnitude of the amplitude of the filter output signal , generates a signal about the technical condition of semiconductor elements on the corresponding indicators.

The disadvantage of this device is the need for preliminary orientation of the sensitivity axis of the magnetic field sensor relative to the control object (rectifier transformer), since at a certain position relative to the magnetic field lines, the output signal will be zero and the device will not work.

A device for the non-contact determination of the technical state of the thyristors of the power source, the closest in the totality of the essential features of the claimed invention [A.G. Sukiyazov and other device for the non-contact determination of the technical state of the thyristors of the power source. Patent for invention No. 2185632, 2002]. The device comprises an external magnetic field measuring transducer (sensor), an amplifier, two phase detectors, a control phase generating device, two level forming amplifiers, an information logical processing device and an information display device.

The disadvantages of the device selected for the prototype are the low reliability of the device due to the large number of elements and functional connections between them, the complexity of the algorithm for obtaining information, as well as the dependence of the shape of the output signal of the sensor (and therefore the result of the device as a whole) on the orientation of its axis sensitivity and the lack of the possibility of influencing the output voltage of the power source in case of failure of the controlled thyristors.

The aim of the invention is to increase the reliability of the device by eliminating the influence of the position of the sensitivity axis of the sensor of the magnetic field relative to the controlled bridge thyristor rectifier, reducing the structural complexity of the device and the algorithm of its operation, as well as providing the ability to maintain a given value of the average rectified voltage in the event of thyristor malfunctions in the bridge circuit rectification by changing the value of the angle of control of the thyristors.

This goal is achieved by the fact that in the automated control device of the bridge thyristor rectifier, the sensor (Fig. 1) of the magnetic field (D) 3 of the current flowing in the supply wires between the power source (IP) 1 and the thyristor rectifier (TV) 2 is placed in a microinductive a solenoid hub of several turns of a supply wire wound on a dielectric cylindrical tube. The sensor output (Fig. 3) is connected to the sensor signal amplifier (V) 4, the output of which is connected to a narrow-band filter (Ф) 5, tuned to a frequency of 2ω (ω is the frequency of the supply thyristor voltage rectifier), the output of which is connected to a logic block (LB ) 6, containing the first comparator (K1) and the second comparator (K2), the switching of the output voltages (operation) of which occurs at different values of the input voltages, with U _in.K2 > U _in.K1 , the output of the comparator K1 is connected to the inputs of logic circuits 2I -NE and 2I, and the output of comparator K2 is connected to a second input of the logical NOR circuit 2I and the second input control system thyristor rectifier, the output of logic NAND 2I connected to the second input of the logic circuit 2I. The output of the logic circuit 2I is connected to the first input of the thyristor rectifier (SUTV) control system 7.

The principle of operation of the inventive device for automated control of a thyristor bridge rectifier is as follows. During the operation of the bridge thyristor rectifier, the current flowing in the current-carrying wires creates a magnetic field, the magnetic flux of which in the micro-inductive solenoid hub is uniquely related to the current strength in the rectification circuit.

If the bridge thyristor rectifier operates in the nominal operating mode and all its elements are operational, only the signals of odd spectral components that are multiples of the main frequency of the voltage supplying the rectifier ω (3ω, 5ω, ...). If the technical state of the thyristors of the rectification circuit changes, the signals of even spectral components that are multiples of the fundamental frequency ω (2ω, 4ω, 6ω ...) additionally appear in the amplitude spectrum of the output signal of the current magnetic field strength sensor.

Figure 2 presents the voltage diagram of a single-phase bridge thyristor rectifier, explaining the essence of the proposed technical solution. With a properly working bridge thyristor rectifier, the value of the _average rectified (output) voltage U _dα1 is determined by the value of the control angle α ₁ received from the control system (figa-c).

If one of the thyristors fails, for example, a thyristor breakage occurs, the bridge circuit is transformed into a half-wave and the value of the _{average rectified} (output) voltage U _dα2 is halved (Fig. 2d). In this case, the current flowing in the circuit is significant for only one half-cycle. As a result, the signals of even spectral components that are multiples of the fundamental frequency ω (2ω, 4ω, ...) additionally appear in the amplitude spectrum of the output signal of the current magnetic field intensity sensor, and at the frequency 2ω the amplitude of the spectral component will be the most significant.

To restore the value of the average rectified (output) voltage to the nominal value (for example, in the absence of the possibility of eliminating the malfunction), it is necessary to reduce the value of the control angle to the corresponding value α ₂ (Fig.2d), which will restore the _{average rectified} voltage to the original value U _dα1 (Fig. 2e).

If a thyristor “breakdown” type malfunction occurs, then in the rectification bridge circuit a situation of a half-wave short circuit is realized, while the signal shape of the current magnetic field intensity sensor differs from the signal shape in the situation with a thyristor “break”, and the amplitudes of even spectral components and, before total, at a frequency of 2ω will increase sharply. To prevent the development of an emergency, it is necessary to stop the operation of the circuit by reducing the value of the thyristor control angle to zero.

Thus, the appearance of even spectral components in the amplitude spectrum of the output signal of the external magnetic field current sensor flowing in the bridge thyristor rectifier circuit (including in the current-conducting wires) will be an unambiguous evidence of the occurrence of thyristor malfunctions in the rectification circuit, leading to deterioration in the quality of the output voltage of the rectifier, or the emergence of an emergency mode of operation, which could lead to failure of both the rectifier itself and the connected Device thereto.

Similar physical processes will occur in a three-phase bridge thyristor rectifier.

A device for automated control of a thyristor bridge rectifier operates as follows. An external magnetic field intensity sensor located inside the micro-inductive solenoid-concentrator forms a signal proportional to the magnitude of the flowing rectified current. In the event that the thyristors of the bridge rectification circuit are operational, the signal from the sensor output after amplification is fed to a narrow-band filter, where its further conversion is terminated due to the absence of a signal component with a frequency of 2ω in it.

If a thyristor breakage or breakdown occurs in the bridge rectification circuit, an even spectral component signal appearing in the sensor output signal with a frequency of 2ω passes through the filter and goes to the inputs of the comparators K1 and K2 of the logic unit, configured to operate at different input signal voltages , and U _in.K2 > U _in.K1 . The use of two comparators in the logic unit, configured to operate at different input voltages, allows you to uniquely determine the technical situation that arose in the bridge circuit of the rectifier. In the event that the thyristor “breaks” in one of the arms of the bridge circuit, the output voltage of the filter Φ becomes greater than U _in.K1 , but less than U _in.K2 , the comparator K1 is triggered. From its output, a signal arrives at the first input (A) of the logic circuit 2I-NOT, the state table of which is presented in Fig. 4a, and at the first input (A) of the logic circuit 2I, the state table of which is shown in Fig.

Since there is no signal at the second input (B) of the 2I-NOT circuit, an output signal will be generated at the output (Q) of the 2I-NOT circuit in accordance with its state table, which will be fed to the second input (B) of the 2I-NOT circuit. In accordance with the state table of this circuit, a signal is generated at its output, which will be fed to the first input of the thyristor rectifier control system. As a result of this, the control system will reduce the value of the control angle, which will lead to the restoration of the average rectified voltage to the required value.

In the event of a critical emergency (“breakdown” of the thyristor of the bridge rectification circuit), which can lead to the failure of the entire rectifier, due to a sharp increase in the signal amplitude of the even spectral component with a frequency of 2ω, when the output voltage of the filter Ф is greater than U _in.K1 and U _{in. K2} , comparators K1 and K2 are triggered. The output of the comparator K1 receives a signal at the first inputs (A) of the logic circuits 2I-NOT and 2I. The output of the comparator K2 receives a signal at the second input (B) of the 2I-NOT circuit. At the same time, the signal is fed to the second input of the thyristor rectifier control system, as a result of which the control system reduces the value of the control angle to zero, and the rectifier turns off. In accordance with the state table of the 2I-NOT circuit, the signal at its output Q, and therefore at the second input (B) of the 2I circuit, will be absent. In accordance with the state table of circuit 2I, there will be no signal at its output.

The proposed device has a significant positive effect, which consists in increasing the reliability of the device by eliminating the influence of the position of the sensitivity axis of the sensor of the magnetic field relative to the bridge thyristor rectifier and the need for its preliminary orientation before making measurements. In addition, the device, which has a simple design and an operation algorithm, allows you to maintain a given value of the average rectified voltage in the event of a malfunction in the bridge rectification circuit due to a change in the value of the control angle.

Claims (1)

A device for automated control of a thyristor bridge rectifier, including a magnetic field sensor, a signal amplifier, a bandpass filter and a logic unit, characterized in that, in order to increase the reliability of the device by eliminating the influence of the sensitivity axis of the magnetic field sensor relative to the controlled bridge thyristor rectifier , simplifying the design and algorithm of work, as well as providing the ability to maintain a given value of the average rectified voltage in the event of a thyristor malfunction in the rectification bridge circuit due to a change in the control angle, the device is equipped with a microinductive solenoid hub, which is a few turns of the thyristor rectifier supply lead, inside of which there is a sensor, the output of which is connected to a signal amplifier, the output of which is connected to the input of a bandpass filter tuned to a frequency of 2ω, where ω is the frequency of the voltage supplying the bridge thyristor rectifier, the output of the polo The filter is connected to the inputs of two comparators of the logic unit having different levels of operation, while the inputs of the logic circuits 2I-NOT and 2I of the logic unit are connected to the output of the comparator, which has a lower level of operation, and the output of the comparator is connected to the second input of the logic circuit 2I-NOT a large level of operation and the second input of the thyristor rectifier control system, and the output of the 2I-NOT logic circuit is connected to the second input of the 2I logic circuit, the first input of the shooting gallery control system is connected to its output a source rectifier, the output of which is connected to the thyristor control electrodes of the bridge thyristor rectifier.

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