SU756049A1 - Device for monitoring turbine rotor heating - Google Patents

Description

The invention relates to a power system and can be used to control the thermally stressed state of the steam turbine rotors, especially during start-up.

The known device for monitoring the heating of the turbine rotor, containing the sensor ₅ steam temperature at a characteristic point of the rotor connected to the unit for calculating the temperature difference across the thickness of the rotor [1].

These devices have low accuracy due to the lack of consideration of the turbine operation mode. Yu

It is also known a device for monitoring the heating of a turbine rotor, comprising a steam temperature sensor at a characteristic rotor point, connected to the first input of the adder, a steam pressure sensor connected via a functional converter to the input of the multiplication unit connected to the second adder input, an integrator and a temperature difference calculator through the thickness of the rotor, to one of the inputs of which is connected the output of the adder [2]. At the outputs of the known device, signals are generated that are proportional to the average rotor temperature and the temperature difference between 2

do rotor heated surface and its average temperature.

This device is the closest to the proposed technical essence and the achieved result.

A disadvantage of the known device should be considered not enough high accuracy and reliability of control due to the limited amount of output information about the thermal state of the rotor.

The purpose of the invention is to improve the accuracy and reliability of control.

To achieve this goal in the proposed device introduced an additional computing unit, made in the form of series-connected integrating links and a summing link, and the output of each integrating link is connected to the input of the first of these links and to the input of the summing link, and connected to the input to the output of the adder, output - with the outputs of the integrator and the multiplication unit, and the output of the adder is connected to the input of the summing element, and the output of the integrator is connected to the input of the unit for calculating the temperature difference.

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756049

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The drawing shows a diagram of the proposed device. The steam temperature sensor 1 at the characteristic point of the rotor 2 is connected to the first input of the adder 3. The steam pressure sensor 4 in the flow section of the turbine is connected to the multiplication unit 5 via a functional converter 6. The output of the adder 3 is connected to the input of the additional calculating unit 7, which is sequentially interconnected integrating links 8 and 9 and summing link 10 at the output. The output of each integrating link 8 and 9 is connected to one of the inputs of the first integrating link 8 and to one of the inputs of the summing link 10. The output of the adder 3 is also connected to one of the inputs of the block 11 for calculating the temperature difference across the rotor thickness and one of the inputs of the summing link 10 included in block 7. The output of block 7 is connected to the input of the integrator 12 and through the multiplication unit 5 with the second input of the adder 3. The output of the integrator 12 is connected to another input of the block 11 for calculating the temperature difference.

The device works as follows.

The adder 3 from the steam temperature sensor 1 receives a signal analogous to the current value of the steam temperature washing the rotor 2, and a signal proportional to the product of the time derivative of the average rotor temperature multiplied by an amount opposite to the Biot criterion. Algebraic summation of these values gives the signal-analogue of the temperature of the heated rotor surface at the output of the adder 3. This signal is fed to a pointing device or a pulse on this signal is used in automatic control. At the same time, the signal analogue of the temperature of the heated surface enters the inputs of blocks 7 and 11. At the output of the last integrating element 9, a signal is obtained analogous to the temperature of the inner bore of the rotor, and at the output of the summing link 10 a signal proportional to the derivative of the average rotor temperature. This signal enters the multiplication unit 5, where it is multiplied by the value opposite to Biot's criterion, which is obtained at the output of the functional converter 6, the input of which is connected to the steam pressure sensor 4 in the flow section of the turbine.

The analogue signal, proportional to the derivative of the average rotor temperature, is also fed to the input of the integrator 12, at the output of which a signal is obtained according to the current value of the average rotor temperature.

5 At the output of block 11 for calculating the temperature difference, a signal analogue of the current temperature difference in the rotor is obtained.

Thus, at the outputs of the device, analog signals of the following quantities are obtained, which characterize the thermal state

10 rotor: temperature of the heated surface of the rotor - output 13; the temperature of the inner bore of the rotor - output 14; the average temperature of the rotor - output 15 and the temperature difference across the thickness of the rotor -

1 exit 16.

This device produces sufficiently complete information about the thermal state of the rotor, which increases the reliability and quality of control.

Claims (1)

Claim 20 A device for monitoring the heating of the turbine rotor, containing a steam temperature sensor at a characteristic rotor point, connected to the first input of the adder, a steam pressure sensor connected via a functional converter to the input of the multiplication unit connected to the second input of the adder, integrator and a unit for calculating the temperature difference across the thickness a rotor, to one of the inputs of which is supplied with keys, an output of the adder, characterized in that, with the aim of increasing the accuracy and reliability of control, an additional block of calculator in the form of series-connected integrating links and a summing link, with ³⁵ than the output of each integrating link is connected to the input of the first of these links and to the input of the summing link, and connected to the input with the output of the adder, output to the inputs of the integrator and the block of mind40 The knockout, and the adder's output is connected to the input of the summing element, and the integrator's output is connected to the input of the unit for calculating the temperature difference.