CS243727B1 - Frequency corrector and retatory magnifier - Google Patents

Abstract

The solution relates to a frequency corrector and speed magnifiers for turbine regulation a addressing improvements in reliability and regulation properties of the turbine especially in the field of phasing speed, increase operational stability turbine block in power control stability and reliability of block operation speed and stability and reliability control when controlling the frequency of the electrification network and improving the phasing process turbines. To fulfill these functions is using two monostable levers, two analog switches, two summators, integrating element, voltage-frequency converter and two output on the one hand, the deviation was evaluated from the desired frequency as DC analog voltage, whose signal is being applied to power control, further expanded otherwise narrow control band in any speed range and evaluated analog DC voltage applied to regulation turbine revolutions and protective circuits. The solution can be used for regulation turbines.

Description

(54)

Frequency corrector and magnifier

The solution concerns frequency corrector and speed magnifier for turbine control and solves improvement of reliability and regulation properties of turbine especially in the field of phasing speed, increasing stability of turbine block operation in power control, stability and reliability of block operation in speed control and stability and reliability in frequency control electricity grid and improvement of the turbine phasing process. To accomplish these functions, two monostable flip-flops, two analog switches, two summers, an integrator, a voltage / frequency converter, and two output amplifiers are used to evaluate the deviation from the desired frequency as a DC analog voltage whose signal is fed into the power control. the otherwise narrow control band is extended in any speed range and the evaluated analog DC voltage is applied to the speed control and turbine protective circuits.

The solution can be used for turbine control.

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243 727

- 1 243 727

BACKGROUND OF THE INVENTION The present invention relates to a frequency corrector and a speed magnifier for controlling turbines, in particular in the phasing speed range.

The systems known hitherto work on the principle of high fixed frequency counting for the period of time, respectively. multiples of the sieve frequency period. during the period evaluated from the pulse frequency of the turbine speed sensor · The deviation from the nominal frequency is evaluated as the output DC voltage · Similarly the selected magnifying glass interval is evaluated as the output DC voltage · The biggest drawback of these wiring is the error resulting from the measurement principle. The error results from the mathematical relation between period T and frequency f when T is valid. - The output DC voltage is dependent on the counting interval T, or · the number of pulses read from this fixed interval from the fixed frequency generator · The dependence between T and f is hyperbolic. The requirement is a linear dependence of the output DC voltage on the input frequency, respectively. deviation from the selected speed sensor frequency (or the nominal grid frequency) · Due to the several percent error resulting from the measurement principle, a complex correction of the DC output voltage is required. Another disadvantage resulting from the measurement principle is the need to preset the counter to a high value corresponding to the frequency of the turbine speed sensor and to subtract the high number from this value. · A small residue after subtracting the corresponding frequency deviation value is evaluated. The absolute evaluation of the relatively small remainder of the counter state is very demanding in terms of accuracy and considerably

- 2 243 727 error-prone · Measurement accuracy and linearity significantly decreases ·

The limitation of hitherto used connections is the use of the magnifying glass only in the area of phasing speed · The current connection methods are very complex, they contain a large number of components ·

Require accurate high-frequency oscillator, multi-bit binary counters, large control and gate circuits, logic memories, digital-to-analog converters, correction circuits · Measurement accuracy and resolution is low · Circuits suffer from high susceptibility to interfering signals · Evaluation always takes place at certain time interval resulting in a step change of the output voltage and also a time delay of the output response to the input frequency change · The time delay depends on the counting interval · The costs of the devices used so far are very high ·

Frequency corrector and speed control for turbine control, characterized in that the input terminal is connected to the input of the first monostable flip-flop whose output is connected to the first input of the first analog switch whose second input is connected to the positive reference terminal, and that the output of the first analog switch is connected to the first input of the first summer whose second input is connected to the output of the second analog switch, and that the output of the first summer is connected to the input of an integrator whose output is connected to the input of the first output amplifier whose output is the first output terminal, on the one hand to the input of the second output amplifier whose output is the second output terminal, and on the other, to the first input of the second summer whose second input is connected to the input control terminal, and whose output is connected via the second monostable flip-flop to the first input of the second analog switch, whose second input is connected to the negative reference terminal ·

The device according to the invention eliminates all the drawbacks and disadvantages of the above, is much simpler and cheaper, and has further advantages over previously used systems.

- 3,243,727 for input frequency change is instantaneous and continuous · Wiring works in continuous dynamic mode with negative feedback · Measurement accuracy and resolution due to negative feedback is high · Dependence of DC output voltage on input frequency deviation is linear · Device listed according to the invention, without the addition of additional circuits, it contains a DC voltage output for both the frequency corrector and the magnifying glass · The connection fully complies with the evaluation accuracy requirements set by the energy standards throughout the measuring and evaluation range. speed and therefore not only in the phase of phasing speed · Selection of the speed magnification mode area is simple by controlling the DC voltage linearly corresponding to the turbine speed range · Another advantage of the invention is Correct change of the frequency corrector range and the magnifying glass range · The change is realized by means of adjustable resistance. The DC output signal is very advantageous in terms of dynamic parameters in steam turbine parameter control applications ·

The frequency corrector and speed magnifier for turbine control are apparent from the attached drawing.

The frequency corrector and the turbine speed control magnifier consist of a first monostable flip-flop 1 which produces a constant pulse width from the input direct frequency coming to the input terminal F1, the output of the first monostable flip-flop 1 being connected to the first input of the first analog switch 2. the second input is connected to the positive reference voltage from the -frUr terminal, and which with frequency. from the first monostable flip-flop 1 switches the positive reference voltage from terminal + Ur. wherein the output of the first analog switch 2 is connected to the first input of the first summer 11, the output of which is connected to the input of the integrator 4, which integrates with the time constant the voltages summed on the first summer 2,

-4243 727 to the input of the first output amplifier 2 by amplifying the frequency corrector range, the output of the first output amplifier 2 being connected to the first output terminal U2. on the one hand to the input of the second output amplifier 10, which amplifies the speed range, the output of the second output amplifier 10 is connected to the second output terminal U3, and to the first input of the second sump 2, clamps Ul. the size of the function selects the frequency corrector and speed magnifier function, while the input resistor size of the second summer 2 ©ern sets the sum weight and thus the frequency corrector and speed magnifier range is selected, the output of the second summer 2 connected to the voltage-frequency converter input it converts its input DC voltage to frequency, the output of the voltage / frequency converter 6 is connected to a second monostable flip-flop 2, which produces a constant pulse width, the output of the second monostable circuit 2 is connected to the first input of the second analog switch 8, the input is connected to the negative reference voltage from the -Ur terminal and which, with the output frequency of the second monostable flip-flop, 2 pins the negative reference voltage at the -Ur terminal. wherein the output of the second analog switch 2 is connected to the second input of the first summer J ·

The system according to the invention operates in such a way that the integrator 6 is controlled by the outputs of two analog switches 2 and 8 of the positive reference voltage at the + Up terminal and the negative reference voltage at the -Ur terminal. which are controlled by two monostable flip-flops 1 and 2 © with constant pulse width, controlled by the input direct frequency from input terminal F1 and the feedback frequency from the second monostable flip-flop 2 · Tí on the integrating element £ direct and feedback · The differential voltage of the positive reference terminal + Ur and the negative reference terminal -Ur of the analog switches 2 and 8 is controlled via the first summator 2, the integrator 6,

5,243,727, which evaluates this difference analogously and weighs the voltage-frequency converter 6, whose nominal frequency is set by the DC control voltage at the input control terminal U1, by this analog signal. This voltage sets the nominal frequency of the frequency corrector and the magnifying glass · The frequency corrector and the magnifying glass are adjusted by the ratio of input resistors in the first and second inputs of the second summator ϋ and by amplifying the first χ and second 10 output amplifier. and the pulse width of the first and second monostable flip-flops 1a, we select the dynamic properties of the circuit. The wiring works as follows: • If the input direct frequency coming to the input terminal F1 increases or decreases with respect to the nominal frequency set by the DC control voltage at the input control terminal U1. the difference between the input direct frequency and the feedback frequency from the second monostable flip-flop X through the first and second analog switches 2 and 8, and the first summator 2 is weighed by the integrating element 6 and the analog voltage at its output increases or decreases. This analog DC voltage increases or decreases through the second summator 2 the voltage-frequency converter frequency until the feedback frequency from the second monostable flip-flop X compares to the direct input frequency of the first monostable flip-flop 1. The deviation from the nominal frequency is evaluated as analog DC voltage at first the output terminal U2 and the second output terminal U3 of the first χ and the second 10 output amplifier.

Frequency and magnifier corrector for turbine control can be advantageously used for regulation and measurement of steam and water turbines, turbo-feeders, in control circuits of controllers for power generators which are driven by all types of turbines, as well as in all devices where analog or Frequently evaluate the deviation from the desired frequency, freely extend the otherwise narrow control band, or. evaluate directly the analogue difference of two frequencies ·

Claims (1)

SUBJECT OF THE INVENTION 243 727 Frequency corrector and speed control for turbine control, characterized in that the input terminal (F1) is connected to the input of the first monostable flip-flop (1), the output of which is connected to the first input of the first analog switch (2) to a positive reference voltage terminal (+ Ur), and the output of the first analog switch (2) is connected to the first input of the first aggregator (3), the second input of which is connected to the output of the second analog switch (8}, the first summer output. is connected to the input of an integrating element (4), whose output is connected both to the input of the first output amplifier (9), the output of which is the first output terminal (U2), and the input of the second output amplifier (10) (U3), and on the other, to the first input of the second sump (5) »whose second input is connected to the input control terminal (U1), and the output of the second sump (5) is connected to tup of the voltage / frequency converter (.6), the output of which is connected via the second monostable flip-flop (7) to the first input of the second analog switch (8), the second input of which is connected to the negative reference terminal (-Ur)