SU760366A1 - Dc electric drive control device - Google Patents

Description

The invention relates to electrical engineering and can be used in electric drives controlled by regulators with sequential correction, which are presented with requirements for increased accuracy and speed in transients, both for control and perturbation. Such are electric drives, for example, rolling mills in metallurgy 10., pressure devices, main drives, manipulators.

A device is known for controlling a direct current electric drive made in accordance with an adjustable system, a 5th converter (thyristor converter or a direct current generator) is an engine containing sequentially connected controllers for position, position, speed and current of 20 anchors [1].

Using the regulators in this device, the drive is tuned for transient functions, the formation of control processes and development of disturbance and limitation of the maximum values of the adjustable parameters.

The introduction of nodes for forcing transients leads to unrecoverable overshoots in current, 30 speed, and position of £ 2] and £ 3}.

This phenomenon is characteristic of all electric drives, since it reflects casts in transients when there is a discrepancy in the settings of the mentioned nodes in time and amplitude with the adjustment of the regulators in accordance with the transition functions and by limitation. The same phenomenon occurs due to a mismatch between the adjustment of the regulators for the transition functions (speed) and the level of restrictions characteristic of the electric drive. ~

Therefore, for example, during control, the current controller accumulates the output voltage faster than it is able to perform the power part of the electric drive. There is a mismatch. by the end of the process, the set and actual voltage, which leads to excessive casting in the process. Such a phenomenon is especially observed in generator-engine systems, since in them the speed that has already been achieved at present is ’limiting in terms of installed capacity and switching processes. The fundamental mismatch between the required slope of the armature current front (on the regulator side) and the actual (in the power part) is the reason for such current surges.

Closest to the proposed technical essence is a device for controlling a direct current electric drive, comprising a series-connected current regulator with a series-connected resistor and capacitor in its feedback circuit (PI regulator) and a voltage regulator with a limiting unit in the feedback circuit [d ].

In this device, the internal voltage control loop serves to linearize the static characteristics of the converter and to improve the use of installed power when working near restrictions. In addition, in valve actuators, the voltage control loop reduces the sensitivity of the drive to disturbances in the supply voltage.

However, in this device, at high amplification factors of the current regulator, it is possible to overshoot it. This limits the increase in the quality and speed of electric drives (according to transient functions), almost completely eliminates the possibility of using force units because of the need to increase the accuracy and stability of their settings.

The purpose of the invention is to increase the speed and accuracy of regulation in transients by eliminating current surges in all processes, ensuring the independence of the settings of regulators and boosting devices.

This goal is achieved by the fact that a non-linear element with a dead band is introduced into the device for controlling a direct current electric drive, containing a series-connected current regulator with a resistor and a capacitor connected in series to its feedback circuit and a voltage regulator with a restriction block in the feedback circuit, input which is connected to the output of the voltage regulator, and the output to the common point of the mentioned resistor and capacitor, while the deadband of the nonlinear element enshe the voltage regulator limits zone.

The drawing shows a diagram of a DC electric drive with the proposed device.

The electric drive contains a DC motor 1 connected to a valve converter 2, in the control circuit of which • a position setting unit 3, a position controller 4, an adder 5 with a restriction, a speed controller consisting of two controllers: integral 6 and proportional 7, controller 8 are sequentially included current and voltage regulator 9. The inputs of the position controller 4, speed 7 and current 8 are connected to the outputs of the relay elements 10, 11, 12, the inputs of which are connected to the outputs of the upstream controllers and to the outputs corresponding to the given sensor control loop: inputs of the relay element 10 - with the outputs of the position setting unit 3 and the sensor 13 positions, inputs of the relay element 11 - with the outputs of the position controller 4 and the sensor 'speed, inputs of the relay element 12 - with the outputs of the speed controller 7 and the current sensor 15. The device also contains non-linear converters 16 and 17, as well as a non-linear element 18 with a dead zone, the input of which is connected to the output of the voltage regulator 9, and the output with the Common point of the resistor 19. and the capacitor 20. The output of the relay element 11 is connected to the input of the speed controller 7 through scale element 21.

In the drawing, the total input signal of each unit of the device is indicated by x, and their output signals are y, k is the value of the limit level of the voltage regulator 9, and t is the deadband of the nonlinear element. 18, £ - time.

The operation of the device is based on a comparison of the inputs of regulators and relay elements of the driving actions with the signals of hard negative feedbacks.

With a constant reference from the output of block 3, the electric drive is in a fixed position, the regulators and relay elements give zero voltage.

When changing the position reference, the regulators 4-9 give a voltage corresponding to the acceleration of the drive. The accumulation of voltage at the output of the current controller 8 leads to an increase in the voltage at the output of the converter 2. The increase in current is limited by the current controller 8., but if the rate of increase in the voltage at the output of the controller 8 is higher than the rate of change of the voltage of the converter 2, then on the capacitor in the feedback circuit of the controller 8 Excessive voltage can accumulate over a period until the voltage at the input of this regulator is equal.

This excess leads to a throw in the armature current and to an emergency shutdown of the drive. Accumulation is excluded by the introduction of a non-linear element 18 with a dead zone. The voltage rise rate of the converter 2 is limited by the level k of the voltage regulator 9. When the voltage at the output of the regulator 9 is increased to k, this voltage is transferred via a nonlinear element 18 (t ί k) to the additional input of the current regulator 8, thereby stopping a further change in the output voltage of this regulator. Overcurrent is completely eliminated.

Similarly, the processes of acceleration and braking of the drive are completed, i.e. casts in speed and position are excluded. At the same time, the task of ensuring the selection of the transfer functions of the regulators is solved, regardless of the installed power of the power unit. In addition, with the introduction of relay elements 10, and 12 and non-linear converters 16, 17, it is only necessary to take into account the limitations in the electric drive, and it is possible to ensure their independent adjustment, including with a dead zone.

Claims (1)

Claim A device for controlling a DC electric drive, made according to the adjustable converter - engine system, containing a regulator connected in series. a current with a resistor and a capacitor connected in series to its feedback circuit and a voltage regulator with a restriction block in the feedback circuit, characterized in that, in order to increase the speed and accuracy of regulation in transient processes, a nonlinear element with a dead zone is introduced into it , the input of which is connected to the output of the voltage regulator, and the output to the common point of the aforementioned resistor and capacitor, while the deadband of the nonlinear element is less than the limit ulyatora voltage.