SU924539A1 - Method and device for checking gas turbine engine rotor component small-cycle fatigue resource exhaustion - Google Patents

Description

(5) METHOD FOR MONITORING THE DEVELOPMENT OF A LOW-CYCLE FATIGUE RESOURCE OF THE COMPONENTS OF THE ROTOR OF A GAS-TURBINE ENGINE AND DEVICE

I

The invention relates to controlling the generation of low-cycle fatigue life of components of rotary machines that are subject to cyclic stresses from their cyclically varying rotational speed, and can be used to record the fatigue damage of rotating components of gas turbine engine rotors.

There is a known method of controlling the generation of low-cycle fatigue life of the components of a rotor of a gas turbine engine by converting in each cycle the rotation frequency of the rotor into equivalent units producing a low-cycle fatigue life, summing the latter and outputting to an indication of 11 3 ..

The known method has the disadvantage that in it the entire range of rotor speed is divided into several sub-bands. To establish the frequency subranges for the implementation thereof

It is necessary to know the type of regularly performed flight, and it is difficult to establish it in advance, since it depends on the operating conditions and atmospheric conditions (1), the method has low accuracy due to the discrete nature of the definition of low-cycle fatigue life.

The purpose of the invention is to improve the accuracy of monitoring the low-cycle fatigue life of the components of the rotor of the engine.

The goal is achieved; that is, the above transformations are performed according to the function of generating a low-cycle fatigue life, the arguments of which are the limiting values of the rotor speed in each cycle, determined from the derivative of the rotation frequency signal.

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Claims (2)

A device is known for monitoring the generation of low-cycle fatigue life of rotor components of a gas-turbine engine, which contains 392 frequency converter for voltage, as well as calculating and zeroing units connected by outputs to the input of an electromechanical counter 11. The known device has low accuracy due to the discrete nature of determination it has a low-cycle fatigue life. The goal of the retention is to increase the accuracy of the device. The goal is achieved by the fact that the device additionally contains a serially connected differentiation unit, a discriminator zero, a program block, an analog-digital converter and a long-term memory block, as well as the first and second RAM blocks, the first and second arithmetic blocks, and the first and second discriminators of the sign, connected by the first inputs and outputs of the corresponding arithmetic blocks, the second to the second output of the program block, and the outputs to the first inputs of the blocks the operating memory and the second input of the program block, the output of the discriminator zero block connected to the second inputs of the analog digital transmitter and the long-term memory block, the third input of which is connected to the third output of the program block connected to the second input of the atomic memory block of the fourth output and the fourth input of the non-volatile memory unit, the first outputs of which are connected by the respective second and third inputs of the computation unit, and the output of the non-volatile memory unit is connected to the third input the second and second inputs of the first RAM, the output of the last of which is connected with the first input of the first arithmetic unit, and the third input - with the first output of the program block and the input of the threshold Element connected by the output with the first input of the second arithmetic unit connected with the second input together with the same input of the first arithmetic unit to the output of the analog-to-digital converter, the third input of which is connected to the output of the frequency converter to voltage together with the input of the Differ unit. The drawing shows a block diagram of the device. The device contains a frequency converter 1 voltage, a computing unit 2, a zero setting unit 3, an electromechanical counter, a differentiation unit 5, a discriminator 6 zero, a software unit 7, an analog-digital converter 8, a non-volatile memory unit 9, the first and second blocks 10 and 11, the first and second arithmetic units 12 and 13, the threshold element 1, and the first and second discriminators 15 and 16 characters. The method is implemented as follows. The signal from the tachometer is converted in the converter 1 into a voltage signal, then this signal is differentiated in block 5 and, when the voltage signal from differentiation block 5 is zero, the discriminator 6 zero is triggered. The signal from discriminator 6 is sent to converter 8, which is connected to the output of block 1 Converter 8 converts the voltage signal that comes from converter 1 to digital. The signal from the block 5 of the decoder 6, the converter 8 propagates much faster than the frequency of the rotor rotor, therefore, the resulting digital signal becomes equal to the value of the extremum of the rotor speed function over time. Simultaneously with the arrival of the signal from the discriminator 6 zero to block 8, a signal is sent to software block 7 which consists of a master clock generator consisting of a set of keys and a trigger, and memory block 9, where a digital signal is stored equal to the value. previous extremum of the rotational speed function over time. Program block 7 sets the bars. Tact 1. A digital signal from block 9 of long-term memory is transmitted to blocks 10 and 11 of the main memory. Tact 2, The signal in block 9 is erased. 1TREY5 the formation of the analog signal and the digital one in block 8 occurs during the first two cycles. Tact 3 "The signal from block 8 is transmitted to block 9 of non-volatile memory, arithmetic blocks 12 and 13" At the same time, a signal is transmitted from block 10 of operational memory 53 to arithmetic block 12, and a signal from the threshold element to arithmetic block 13. In In arithmetic units 12 and 13, a subtraction operation is performed. In block 12, from the digital signal of converter 8, equal to the extremum of the function of the frequency of rotation over time, subtracted the unit's signal; 10, equal to the previous extremum of the function of the rotational speed. If the difference obtained is smaller than zero, the units of the fatigue life are not calculated, It is said that, in order to simplify the device, resource units are calculated only when the rotational speed increases. In block 13, the digital signal of block 11 is subtracted from the digital signal of block 9, which is equal in magnitude to a certain limit value of the rotation frequency, i.e. This frequency of rotation of the rotor, less than which the development of low-cycle fatigue life is insignificant. Consequently, if the resulting oasnrst in block 13 is less than zero, then no further calculations are performed. Tact Discriminators 15 and 16 characters determine the signs of the numbers in the arithmetic blocks 12 and 13. If at least one of them is less than zero, a signal is sent to program block 7 and blocks 10 and 11. Program block 7 is turned off, and in blocks 10 and 11 of the RAM is reset the digital signals recorded there. T and to t 5. Digital signals from blocks 9 and 11 are fed to block 2, 8, block 2, the calculation of the resource generation function is performed for cycling the rotor speed from one extremum to another, after which the result is fed to an electromechanical counter 4, where it is added to the previously accumulated sum of units low-cycle fatigue life. The time taken for the device to take five cycles and the calculation of resource units is insignificant. After the end of the passage of a given extremum of the function of the frequency of rotation over time, its value is stored in block 9 until the moment of passage of the next extremum. Calculations occur only when passing a maximum. The indicator of the electromechanical counter is displayed in the cockpit of the aircraft. With the help of block 3, the electromechanical counter can be set to zero. Thus, the proposed invention allows to increase the accuracy of the calculation of the production of low-cycle fatigue life and, thereby, to increase the efficiency of the systems for controlling the production of the resource. Claim 1. Method of controlling generation of low-cycle fatigue () resource of rotor components of a gas turbine engine by converting in each cycle the rotation frequency of the rotor into equivalent units of low-cycle fatigue life, summing up the latter and outputting an indication that, These transformations are performed according to the function of generating a low-cycle fatigue life, the arguments of which are the boundary values of the rotor rotation frequency in each cycle. , Determined / 1c 's oT on production, the rotational speed signal. 2. A device for controlling the generation of low-cycle fatigue life of the components of a rotor of a gas turbine engine, containing a frequency converter for voltage, as well as calculating and zeroing units connected by outputs to an input of an electromechanical counter, characterized in that, in order to improve accuracy, it also contains a series-connected differentiation unit, a discriminator zero, a program block, an analog-digital converter and a non-volatile memory block, as well as the first and second blocks memory modules, first and second arithmetic blocks, threshold element and first and second sign discriminators connected by the first inputs and outputs: the corresponding arithmetic blocks, the second to the second output of the program block, and the outputs to the first inputs of the RAM and the second the input of the program block, the output of the discriminator block zero being connected to the second inputs of the analog-digital converter and the block for a long time