RU2466453C1 - System to prevent sticking of spools and sleeves of fuel-controlling equipment of aviation gas turbine engines by means of ultrasonic excitation of vessel - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: system comprises a module for identification of a basic address of an avia engine, a module for generation of a relative address of a controller pump, a module for generation of signals of spool vessel parameters reading, a module for registration of spool vessel parameters, a module to generate signals of spool parameters reading, a module for registration of spool parameters, a module for generation of signals for calling of a subprogramme of a server data base, a module for identification of spool and sleeve condition, a module for selection of a basic address of ratios between sound speed in a material of a spool vessel to spool length, a module for generation of signals to read ratio between sound speed in the spool vessel material to spool length, a module to identify frequency of ultrasonic oscillations of the spool vessel, a module to identify capacity of ultrasonic oscillations of the spool vessel.

EFFECT: higher efficiency of a system through exclusion of data searching in entire volume of a server data base and confining search only in reference addresses of a data base, corresponding to identifiers of an avia engine, a controller pump, a spool vessel and a spool itself in fuel-controlling equipment of an avia engine, and speed of sound oscillations distribution in a spool vessel material.

13 dwg

Description

The invention relates to computer technology, in particular to a system for preventing sticking of slide valves of fuel control equipment of aircraft gas turbine engines by ultrasonic excitation of the housing, which implements the use of new information technologies in the diagnosis of fuel equipment of aircraft engines.

Failures of slide valves of fuel control equipment (TPA) of aircraft gas turbine engines (GTE) are one of the main reasons for spontaneous shutdown of engines in flight. This takes place not only on domestic aircraft, but also on foreign aircraft.

The reason for such failures is the decrease in fuel quality associated with the formation of deposits, resins and mechanical impurities in the gap between the spool and the sleeve. This leads to an increase in friction forces up to the complete jamming (sticking) of the spool in the sleeve. Sticking of the spool is identified by a special coefficient called the damping (attenuation) coefficient ξ.

In [3], for the damping coefficient ξ of the spool pair, an expression was obtained depending on the viscosity ν and density ρ of the fuel, friction area S, gap δ between the spool and the sleeve, the mass of deposits m _from contaminants in the gap δ, spring stiffness k and the mass of the spool m _z .

In expression (1), the values of ρ, S, δ, k, m _z are constant, they do not change during the time the product is in operation.

During long-term operation of the aircraft engine, the viscosity ν in the vicinity of the spool and the mass of deposits m _from in the gap δ increase, which leads not only to an increase in the damping coefficient ξ of the spool pair, but also to complete sticking of the spool.

Clogging of the TPA spools of an aircraft gas turbine engine leads to engine failure at the stage of flight where these spools should operate: the beginning of the decline is the constant pressure differential valve (KPPD) on the throttle valve, the mileage during landing are the spools for controlling the transfer of blades of the adjustable guide vane, reverse control and other

In [4] gives a solution to the problem of determining the parameters (frequency and power) of the ultrasonic excitation of the spool body mass m _k, necessary and sufficient for the separation _of the slide mass m and length l _of casing retained in the dry friction force F _tr.

Further displacement of the spool after its separation is considered as a problem of propagation of longitudinal vibrations excited by an ultrasonic generator that implements periodic displacement of the end face of the spool according to the law

where y ₀ is the amplitude of the longitudinal displacement, ω is the circular frequency (the number of longitudinal vibrations in 2π seconds).

In this case, each point of the housing (including the spool) experiences acceleration

Therefore, the inertial force acts on the spool

превышала силу сухого трения покоя F_тр, т.е. должно выполняться условиеTo detach the spool, it is necessary and sufficient that the inertial force acting on the spool

exceeded the force of dry friction of rest F _Tr , i.e. the condition must be met

Where

To ensure possible displacement of a stuck spool, its length l _s should be covered by a half-wave λ / 2 of longitudinal vibrations, i.e. the condition must be met

Only in this case the entire spool is in one phase of displacement.

At the same time, for the wavelength λ, the condition

where c is the speed of sound in the material of the valve body, f is the frequency of longitudinal vibrations.

Then from (7) and (8) for the wavelength λ of longitudinal vibrations we obtain

Whence the frequency f of longitudinal vibrations must satisfy the condition

The kinetic energy of the oscillations of the valve in the phase of maximum speed has the form

получает видExpression (11) taking into account

gets the look

Hence, the power of ultrasonic excitation per spool has the form

From (13) it follows that the power of the U3 emitter necessary to excite the oscillations of the valve body of mass m _k is determined by the expression

Substituting in (14) j _max = y ₀ (2π) ² f ² from (6), we obtain

и мощностью

.The above considerations show that for tearing off a stuck spool from the body, it is necessary and sufficient to excite the spool body with ultrasonic vibrations with a frequency

and power

.

Thus, characterizing the state of the spool by the amplitude of its free vibrations, it is of interest to develop such an automated system that would prevent possible sticking of the spool in the housing by excitation of the spool by ultrasonic vibrations, the parameters of which are identified by the system in each case of fixing the valve’s precarious state.

Known systems that could be used to solve the problem [1, 2].

The first of the known systems comprises data reception and storage units connected to control and data processing units, search and selection units connected to data storage and display units, the synchronizing inputs of which are connected to the outputs of the control unit [1].

A significant drawback of this system is the impossibility of solving the problem of updating data stored in memory in the form of relevant documents, simultaneously with solving the problem of delivering the contents of these documents to users in real time.

Another system is known, containing a central processor module, the inputs of which are connected to the memory modules and to the data preparation and input modules, and the outputs are connected to the corresponding memory modules, the data processing module, the information inputs of which are connected to the outputs of the corresponding memory modules, the synchronizing inputs are connected to control outputs of the central processor module, and the output of the module is the information output of the system [2].

The last of the above technical solutions is closest to the described.

Its disadvantage lies in the low speed of the system, due to the fact that the implementation of analytical data processing procedures is carried out by searching the entire database, which, when the database is large, inevitably leads to unreasonably large time spent on obtaining analytical estimates.

The purpose of the invention is to increase the system performance by excluding data search over the entire volume of the server database and localizing the search only at the reference (fixed) database addresses, corresponding identifiers of the aircraft engine, pump regulator, valve body and the valve core of the aircraft engine fuel control equipment, as well as the propagation speed sound vibrations in the valve body material.

This goal is achieved by the fact that in the system containing the identification module of the base address of the aircraft engine, the information input of which is the first information input of the system, designed to receive the request codogram from the workstation of the user of the system, the synchronizing input of the identification module of the base address of the aircraft engine is the first synchronizing input of the system, intended for receiving synchronization signals of entering the request codogram from an automated working m one hundred system users in the aircraft engine base address identification module, the controller-pump relative address generation module, the first and second information inputs of which are connected to the first and second aircraft engine identification address base identification module, respectively, the synchronizing input of the pump-controller relative address formation module is connected to the synchronizing output module identification base address of the aircraft engine, a module for generating signals for reading parameters spool housing, one information input of which is connected to the information output of the module for generating the relative address of the pump-regulator, and another information input of the module for generating signals for reading the parameters of the valve body is connected to the third information output of the module for identifying the base addresses of the aircraft engine, synchronizing the input of the module for generating signals for reading the parameters of the valve body connected to the synchronizing output of the module forming the relative address of the pump-controller , one information output of the module for generating signals for reading the parameters of the valve body is the first address output of the system designed to provide the address of the valve body for the address input of the database server, and the synchronizing output of the module for generating signals for reading the parameters for the valve body is the first synchronizing output of the system for issuing signals control of reading the parameters of the valve body to the input of the first channel of the database server interrupt, registration module and parameters of the valve body, the information input of which is the second information input of the system, intended for receiving codes of valve case parameters read from the server database, the synchronizing input of the valve body parameters registration module is the second synchronizing input of the system, for receiving signals for entering the valve body parameter codes read from the server database to the valve body parameter registration module, the module for generating read signals spool meter, one information input of which is connected to another information output of the module for generating signals for reading the parameters of the valve body, and another information input for the module for generating signals for reading the parameters of the valve is connected to the fourth information output of the module for identifying the base address of the aircraft engine, which synchronizes the input of the module for generating signals for reading the parameters of the valve to the synchronizing output of the module for registering the parameters of the valve body, inform the output of the module for generating signals for reading the parameters of the spool is the second address output of the system designed to provide the address of the spool for the address input of the database server, and the synchronizing output of the module for generating signals for reading the parameters of the valve is the second synchronizing output of the system for issuing control signals for reading the parameters of the spool input of the first channel for interrupting the database server, module for registering spool parameters, information input is the third information input of the system, intended for receiving codes of spool parameters read from the server database, the synchronizing input of the spool parameters registration module is the third synchronizing input of the system, for receiving signals of entering codes of spool parameters read from the server database into the registration module spool parameters, a module for identifying the power of ultrasonic vibrations of the spool body, the first and second information inputs of which are connected are assigned to the fifth and sixth information outputs of the aircraft engine base address identification module, respectively, the third information input of the valve body ultrasonic vibration power identification module is connected to one information output of the valve body parameters registration module, the information output of the ultrasonic vibration power identification module of the valve body is the first information output of the system, intended for issuing a power code of ultrasonic vibrations of a gold body As to the automated workstation of the user of the system, the synchronizing output of the module for identifying the power of ultrasonic vibrations of the spool housing is the first signal output of the system designed to provide an identification signal for the power code of ultrasonic vibrations of the spool housing to the automated workstation of the user of the system, according to the invention, a module for generating signals for calling the base subprogram server data, the information input of which is connected to one information the spool parameter registration module, the synchronizing input of the server database subroutine call signal generation module is connected to the spool parameter registration module, the information output of the server database subroutine signal generation module is the second information output of the system designed to issue fuel viscosity codes in the vicinity of the spool , fuel density, mass of deposits, friction area, the gap between the spool and the sleeve, the stiffness of the spring and the spool mass to the information input of the database server, and the synchronizing output of the module for generating call signals of the server database subroutine is the third synchronizing output of the system designed to issue control signals for calling the server database subroutine to the input of the second channel of the database server interrupt, the valve pair identification module , one information input of which is the fourth information input of the system, designed to receive codes of coefficients dem spool pair read from the server database, another information input of the spool pair identification module is connected to the seventh information output of the aircraft engine base address identification module, the synchronizing input of the spool pair identification module is the fourth synchronizing input of the system designed to receive signals for entering damping coefficient codes the spool pair read from the server database to the golden state identification module of a single pair, one synchronizing output of the spool pair identification module is the second signal output of the system, intended for issuing a signal identifying the working state of the spool pair to the workstation of the system user, and is connected to one installation input of the identification module of the base address of the aircraft engine, with one installation input of the module generating signals for reading parameters of the valve body, with one installation input of the parameter registration module the valve body, with one installation input of the module for generating signals for reading the parameters of the valve, with one installation input for the module for registering parameters of the valve, with one installation input for the module for generating signals for calling the server database subroutine, the other synchronizing output of the module for identifying the state of the valve pair is the third signal output of the system, designed to issue a signal identifying the precautionary state of the spool pair at a workstation pol of the system spool, the module for selecting the base address of the relations of sound speed in the material of the valve spool to the length of the spool, the information input of which is connected to another information output of the module for registering parameters of the valve spool, and the synchronizing input of the module for the selection of the base address of the relations of sound speed in the material of the spool is connected to the length of the spool to another synchronizing output of the spool pair state identification module, a module for generating read signals of the sound velocity ratio in the material of the valve body to the length of the valve, one information input of which is connected to the information output of the selection module of the base address of the relations of sound speed in the material of the valve body to the length of the valve, the other information input of the module for generating signals for reading the ratio of the speed of sound in the material of the valve body to the length of the valve another information output of the spool parameter registration module, synchronizing the input of the module for generating signals for reading the speed ratio sound and in the material of the valve body to the length of the valve is connected to the synchronizing output of the selection module of the base address of the speed of sound in the material of the valve to the length of the valve, the information output of the module for generating signals for reading the ratio of the speed of sound in the material of the valve to the length of the valve is the third address output of the system to provide the address of the ratio of the speed of sound in the material of the valve body to the length of the valve on the address input of the database server, and the synchronizing you the course of the signal generation module for reading the ratio of the speed of sound in the material of the spool body to the length of the spool is the fourth synchronizing output of the system designed to provide control signals for reading the ratio of the speed of sound in the material of the body of the spool to the length of the spool to the input of the first channel of the database server interrupt, and the frequency identification module ultrasonic vibrations of the valve body, the information input of which is the fifth information input of the system, designed to receive codes of ratios of sound velocity in the material of the spool housing to the length of the spool read from the server database, the synchronizing input of the module for identifying the frequency of ultrasonic vibrations of the spool housing is the fifth synchronizing input of the system designed to receive signals for entering codes of ratios of the speed of sound in the material of the housing of the spool to the length of the spool, read from the server database, into the module for identifying the frequency of ultrasonic vibrations of the valve body, the information output of the identification module h The frequency of ultrasonic vibrations of the valve body is the third information output of the system, intended for issuing frequency codes of ultrasonic vibrations of the valve body to the workstation of the user of the system, and is connected to the fourth information input of the module for identifying the power of ultrasonic vibrations of the valve body, and the synchronizing output of the module for identifying the frequency of ultrasonic vibrations of the case the spool is the fourth signal output of the system, intended for issuing the identification signal of the frequency code of ultrasonic vibrations of the valve body to the automated workstation of the user of the system, and is connected to the synchronizing input of the module for identifying the power of ultrasonic vibrations of the valve body, while the synchronizing output of the module for identifying the power of ultrasonic vibrations of the valve body is connected to another installation input of the identification module of the base address of the aircraft engine, with another installation input of the module for generating signals for reading parameters of the case the spool, with a different installation input of the valve body parameter registration module, with another installation input of the spool parameter reading signal generation module, with another installation input of the spool parameter registration module, with another installation input of the server database subroutine call signal generation module, with the installation input of the identification module the frequency of ultrasonic vibrations of the valve body and with the installation input of the module for generating signals for reading the sound velocity ratio in the spool body material to the length of the spool.

The invention is illustrated by drawings, where Fig. 1 is a structural diagram of a system, Fig. 2 shows an example of a specific structural implementation of a module for identifying a base address of an aircraft engine, Fig. 3 is an example of a specific constructive implementation of a module for generating a relative address of a pump controller; 4 is an example of a specific constructive implementation of a module for generating signals for reading parameters of a valve body, and FIG. 5 is an example of a specific constructive implementation of a module for recording parameters of a core 6, an example of a specific structural implementation of a module for recording parameters of a valve, Fig. 7 is an example of a specific constructive implementation of a module for registering parameters of a valve, and Fig. 8 is an example of a specific structural implementation of a module for generating signals for calling a server database subroutine. , Fig.9 is an example of a specific constructive implementation of the module for identifying the state of the spool pair, Fig.10 is an example of a specific constructive implementation of the module for selecting the base hell Fig. 11 shows an example of a specific constructive implementation of a module for identifying the frequency of ultrasonic vibrations, Fig. 11 is an example of a specific constructive implementation of a module for generating signals for reading the ratio of the speed of sound in a material of a body of a spool to a length of a spool. the valve body, Fig. 13 is an example of a specific structural implementation of the module for identifying the power of ultrasonic vibrations of the valve body.

The system (Fig. 1) contains a module for identifying the base address of the aircraft engine, a module 2 for generating the relative address of the pump controller, a module 3 for generating signals for reading parameters of the valve body, module 4 for registering parameters for the valve body, module 5 for generating signals for reading valve parameters, module 6 for registration spool parameters, module 7 for generating call signals of the server database subroutine, module 8 for identifying the state of the spool pair, module 9 for selecting the base address of the c sound velocity in the material of the valve body to the length of the valve, module 10 for generating signals for reading the ratio of the speed of sound in the material of the valve body to the length of the valve, module 11 for identifying the frequency of ultrasonic vibrations of the valve body, module 12 for identifying the power of ultrasonic vibrations of the valve body.

Figure 1 shows the first 15, second 16, third 17, fourth 18 and fifth 19 information inputs of the system, the first 20, second 21, third 22, fourth 23 and fifth 24 synchronizing inputs of the system, as well as address 25-27, information 28 -30, synchronizing 31-34 and signal 35-38 system outputs.

The aircraft engine base address identification module 1 (FIG. 2) contains a register 40, a decoder 41, a memory module 42 made in the form of read-only memory (ROM), AND elements 43-45, OR element 46, delay elements 47-48. The drawing also shows information 49, synchronizing 50 and installation 51-52 inputs, information 60-66 and synchronizing 67 outputs.

Module 2 for the formation of the relative address of the pump controller (Fig. 3) contains a decoder 70, a memory module 71, made in the form of read-only memory (ROM), an adder 72, elements And 73-75, elements 76-77 delay. The drawing also shows information 78-79 and synchronizing 80 inputs, information 81 and synchronizing 82 outputs.

Module 3 for generating signals for reading the parameters of the valve body (Fig. 4) contains a decoder 83, a memory module 84 made in the form of read-only memory (ROM), an adder 85, a register 86, AND 87-89 elements, an OR element 90, elements 91- 93 delays. The drawing also shows information 95-96, synchronizing 97 and installation 98-99 inputs, information 100-101 and synchronizing 102 outputs.

Module 4 registration parameters of the valve body (figure 5) contains a register 105, an OR element 106 and a delay element 107. The drawing also shows information 108, synchronizing 109 and installation 110-111 inputs, information 112-113 and synchronizing 114 outputs.

The module 5 for generating signals for reading the parameters of the spool (Fig. 6) contains a decoder 120, a memory module 121, made in the form of read-only memory (ROM), an adder 122, register 123, AND elements 124-126, OR element 127, elements 129-131 delays. The drawing also shows information 132-133, synchronizing 134 and installation 135-136 inputs, information 137 and synchronizing 138 outputs.

The valve parameter registration module 6 (FIG. 7) comprises a register 140, an OR element 141, and a delay element 142. The drawing also shows information 143, synchronizing 144 and installation inputs 145-146, information 147-148 and synchronizing 149 outputs.

Module 7 generating signals of the call subroutine of the server database (Fig) contains a register 150, an OR element 151 and a delay element 152. The drawing also shows information 153, synchronizing 154 and installation inputs 155-156, information 157 and synchronizing 158 outputs.

The valve pair identification module 8 (Fig. 9) comprises a register 160, a comparator 161, an OR element 162, and a delay element 163. The drawing also shows information 164-165 and synchronizing 166 inputs, synchronizing 169-170 outputs.

Module 9 selection of the base address of the relationship of the speed of sound in the material of the valve body to the length of the valve (figure 10) contains a decoder 173, a memory module 174, made in the form of read-only memory (ROM), elements And 175-177, delay element 178. The drawing also shows information 179 and synchronizing 180 inputs, information 181 and synchronizing 182 outputs.

Module 10 for generating read signals of the ratio of the speed of sound in the material of the valve body to the length of the valve (Fig. 11) contains a decoder 185, a memory module 186, made in the form of read-only memory (ROM), adder 187, register 188, elements 189-191, delay elements 193-195. The drawing also shows information 196-197, synchronizing 198 and installation 199 inputs, information 200 and synchronizing 201 outputs.

Module 11 for identifying the frequency of ultrasonic vibrations of the valve body (Fig. 12) comprises a register 204, a shift register 205, and delay elements 206-207. The drawing also shows information 208, synchronizing 209 and installation 210 inputs, information 211 and synchronizing 212 outputs.

The module 12 for identifying the power of ultrasonic vibrations of the valve body (Fig. 13) contains multipliers 215-219, shift registers 220-221, delay elements 222-228. The drawing also shows information 230-233 and synchronizing 234 inputs, information 236 and synchronizing 237 outputs.

All nodes and elements of the system are made on standard potential-impulse elements.

The remote automated workstation (AWP) of the system user consists of a terminal having a screen for displaying the request codogram and system signals and the keyboard of a personal computer. The presentation of readable parameters of the valve body and the valve itself, as well as the presentation of the damping coefficient of the valve pair and the ratio of the speed of sound in the material of the valve body to the length of the valve are controlled from the server (not shown).

The system operates as follows.

The system associates an aircraft engine and each device of its fuel control equipment with an identification number — a digital code. In addition, the aircraft engine code corresponds to a certain base address of the server database memory, and the codes of the devices of its fuel control equipment correspond to offset codes, which determine the relative addresses of these devices in the server database memory when reading information about the parameters stored in them.

In this case, the relative address of the pump regulator is shifted relative to the base address of the aircraft engine, the address of the spool housing is shifted relative to the relative address of the pump regulator, and the address of the spool is shifted relative to the relative address of the spool housing.

Thus, the aircraft engine code opens its base address in the memory of the server database. Then, the identifier of the pump regulator determines its displacement code, which, summing up with the code of the base address of the aircraft engine, determines the relative address of the pump regulator in the memory of the server database.

An offset corresponding to the valve body code is added to the received relative address of the pump regulator, and the relative address of the valve body is formed, which is sent by the system to the address input of the database server.

By the system signal, which is input to the first channel of the server interrupt, the server polls the contents of its database at the received address and provides the read parameters of the valve body to the information input of the system.

Next, the system generates the relative address of the spool (spool pair) by adding to the relative address of the spool body a certain offset corresponding to the ID of the spool, and provides the generated new address to the address input of the database server.

By the signal of the system, which also arrives at the input of the first channel of the server interruption, the server again polls the contents of its database at the received new address and issues the read spool parameters to the information input of the system.

The system, having received the parameters of the spool pair, contacts the server to execute a subroutine on the received data of the spool pair. For this, the system sends the spool pair parameters to the server information input and sends a signal to the input of the second interrupt channel.

According to the system signal, which is input to the second channel of the server interrupt, the server polls its information inputs, takes the spool pair parameters issued by the system from the system information output, and returns from its database to the system information input a correspondence in the form of a spool damping (attenuation) code couples.

Further, the system compares the obtained damping coefficient with a certain attenuation threshold adopted by the system according to the codogram of the request from the user of the system. If the damping coefficient received by the system from the server is less than the attenuation threshold set by the request codogram, then the working state of the spool pair is recorded. In this case, the system returns to its original state.

If the damping coefficient is equal to or greater than the set attenuation threshold, then a signal is generated that fixes the precarious state of the spool. By this signal, the system identifies the parameters (frequency and power) of ultrasonic vibrations that are necessary and sufficient to prevent possible sticking of the spool in the housing, and sends them to the user's workstation, and then also returns to its original state.

The oscillation amplitude of the spool in good condition is established based on the analysis of the vibrational spectrum of the oscillations of the pump regulator at the previous stage of operation. In this case, the engine runs at steady state (for example, small gas), and the vibrational spectrum is obtained using vibrational equipment such as "Quartz".

When monitoring the current state of the spool pair by spectral analysis of vibrations of the spool, on the end of the body of which a piezoelectric accelerometer is installed, the amplitude of the spool vibrations is determined.

To start the system, the user at his workplace generates a request codogram, which indicates the identifier of the aircraft engine, the identifier of the pump regulator, the identifier of the spool housing, the identifier of the spool, the threshold value of the attenuation coefficient, the value of the amplitude of the free oscillations of the spool and some calculated coefficient of increase in power:

The code The code The code The code The code The code The code Enter aircraft engine ID The identifier of the regulator pump is entered. Enter differential pressure constant valve identifier Spool ID entered The threshold value of the attenuation coefficient is introduced, ξ is the _threshold Enter the value of the amplitude of the oscillations of the spool, y ₀ Enter the value of the coefficient of increase in power, π ^s

The codogram from the workstation of the user of the system is fed to the information input 15 of the system, fed to the information input 49 of the identification module 1 of the aircraft engine base address and entered into the register 40 by a clock pulse supplied to the clock input 50 of module 1 from the clock input 20 of the system.

The code of the aircraft engine from the output 53 of the register 40 is fed to the input of the decoder 41. The decoder 41 decrypts the code of the aircraft engine and generates at one of its outputs a high potential supplied to the corresponding inputs of the elements And 43-45. For definiteness, let us assume that the high potential from the output of the decoder 41 will open the And element 45 at one input.

The clock pulse from the input 20 of the system, passing through the input 50 of module 1, is delayed by the delay element 47 for the response time of the register 40 and the decoder 41 and enters through the element And 45, which is open one at a time, to the read input of a fixed cell of a read-only memory (ROM) 42.

In a fixed cell of the ROM 42, the code of the aircraft engine's base address is stored, starting from which the server database stores information on the parameters of all devices of the fuel control equipment of this aircraft engine (pump regulator, valve body, spool).

Each of the aforementioned devices of the aircraft engine fuel control equipment also has its own address in the memory of the server database. But these addresses are identified as relative addresses and are formed by offsetting either relative to the base address of the aircraft engine, or relative to each other's relative addresses. In this case, the offset code of the relative address of each of the devices of the fuel control equipment of the aircraft engine is determined by its identifier code.

Therefore, the code of the pump controller of the aircraft engine from the output 61 of module 1 is sent to the information input 78 of the module 2 for generating the relative address of the pump controller and is supplied to the input of the decoder 70. The decoder 70 decodes the code of the pump controller and generates a high potential at one of its outputs corresponding inputs of elements AND 73-75. For definiteness, let us assume that the high potential from the output of the decoder 70 will open the And 75 element at one input.

The synchronizing pulse from the output of the delay element 47, delayed by the delay element 48 while reading the contents of the fixed cell of the ROM 42 and the decoder 70 is activated, from the output 67 of the module 1 is sent to the synchronizing input 80 of the module 2 and fed through the I 75 element open through one input to the read input a fixed cell of read-only memory (ROM) 71. The fixed cell of the ROM 71 stores a code for shifting the address of the pump regulator relative to the base address of the aircraft engine.

This code from the output of the ROM 71 is fed to one information input of the adder 72, to the other information input 79 of which the code of the base address of the aircraft engine from the output 60 of module 1 is supplied.

According to the synchronizing pulse from the input 80 of module 2, delayed by the delay element 76 for the read time of the fixed cell of the ROM 71, the relative address of the pump controller is formed in the adder 72.

The valve body code from the output 62 of module 1 is sent to the information input 95 of the module 3 for generating signals for reading the parameters of the valve body and supplied to the input of the decoder 83. The decoder 83 decodes the valve body code and generates a high potential at one of its outputs, which goes to the corresponding inputs of the elements And 87-89. For definiteness, let us assume that the high potential from the output of the decoder 83 will open the element And 87 on one input.

The synchronizing pulse from the output of the delay element 76, delayed by the delay element 77 during the operation of the adder 72 and the decoder 83, from the output 82 of the module 2 is sent to the synchronizing input 97 of the module 3 and fed through the element 87 open to the reading input of the fixed cell device (ROM) 84. In a fixed cell ROM 84 is stored code offset address of the valve body relative to the relative address of the pump controller.

The code for shifting the address of the spool housing, read from the ROM 84, is supplied to one information input of the adder 85, to the other information input 96 of which the code of the relative address of the pump regulator is output from the output 81 of module 2. By a synchronizing pulse from the input 97 of module 3, delayed by the delay element 91 the read time of the fixed cell ROM 84, in the adder 85 the formation of the relative address of the valve body.

This address from the output of the adder 85 goes to the information input of the register 86, where it is entered by the synchronizing pulse from the output of the delay element 91, delayed by the delay element 92 for the duration of the operation of the adder 85.

The same pulse from the output of the delay element 92 is delayed by the delay element 93 for the time the code of the relative address of the spool housing is entered into the register 86 and from the output 31 of the system is input to the first channel of the server interrupt.

With the arrival of this impulse, the server switches to the subprogram for polling the contents of its database at the address generated on the address output 25 of the system, and issuing the read parameters of the valve body to the information input 16 of the system.

The parameters of the valve body read from the server database from the information input 16 of the system go to the information input 108 of the register 105 of the module 4 for registering the parameters of the valve housing, where they are entered by the synchronizing pulse of the server to the system input 21.

The parameters of the valve body in the register 105 are represented by two codes:

Valve body parameters The code The code The speed of sound propagation in the material of the valve body, C The mass of the valve body, m _to

The code of sound speed in the material of the valve body from the output 112 of module 4 is sent to the information input 179 of the module 9 for selecting the base address of the relationship of the speed of sound in the material of the valve body to the length of the valve and is fed to the input of the decoder 173. The decoder 173 decodes the code of the speed of sound in the material of the valve body and generates at one of its outputs a high potential supplied to the corresponding inputs of elements And 175-177. For definiteness, let us assume that the high potential from the output of the decoder 173 will open the And 175 element at one input.

At another input, the And element 175 will be closed until a pulse arrives at the synchronizing input 180 of module 9 from the output 169 of the comparator 161 of module 8.

The spool code from the output 63 of module 1 is sent to the information input 132 of the spool parameter readout module 5 and fed to the input of the decoder 120. The decoder 120 decrypts the spool code and generates a high potential at one of its outputs that goes to the corresponding inputs of the I 124-126 elements . For definiteness, let us assume that with the high potential from the output of the decoder 120, the And 125 element will be open at one input.

In this case, the server synchronizing pulse from the system input 21, delayed by the delay element 107 for the time the spool case parameters were entered into the register 105 and the decoder 120 is triggered, is sent from the output of module 4 to the synchronization input 134 of module 5 and received through the I element open through one input 125 to the read input of a fixed cell of read-only memory (ROM) 121. In a fixed cell of ROM 121, a code for shifting the spool address relative to the relative address of the spool housing is stored.

The code for shifting the address of the spool read from the ROM 121 is supplied to one information input of the adder 122, the other information input 133 of which is supplied with the code of the relative address of the body of the spool from the output 101 of module 3. By a clock pulse from the input 134 of module 5, delayed by the delay element 129 for the read time fixed cell ROM 121, the adder 122 is the formation of the relative address of the spool.

This address from the output of the adder 122 is fed to the information input of the register 123, where it is entered by the synchronizing pulse from the output of the delay element 129, delayed by the delay element 130 for the duration of the operation of the adder 122.

The same pulse from the output of the delay element 130 is delayed by the delay element 131 for the time the code of the relative spool address is entered in the register 123 and from the output of the system 32 is fed to the input of the first channel of the server interrupt.

With the arrival of this impulse, the server switches to a subprogram for polling the contents of its database at the address generated on the address output 26 of the system and issuing the read spool parameters to the information input 17 of the system.

The spool parameters read from the server database from the information input 17 of the system go to the information input 143 of the register 140 of the module 6 for registering the parameters of the spool, where they are entered by the synchronizing pulse of the server to the input 22 of the system.

The accepted spool parameters are divided into two groups of codes:

Spool parameter codes Group G1 Group G2 the code the code the code the code the code the code the code the code Spool length, l _s Fuel density, ρ Fuel viscosity in the vicinity of the spool, ν Friction Area, S The gap between the spool and the sleeve, δ The mass of sediment in the gap, m _from Spring stiffness, k Spool mass, m _s

The spool length code from the spool parameter group G1 from the output 148 of the module 6 is sent to the information input 196 of the signal generation module 10 for reading the ratios of the speed of sound in the spool body material to the spool length and is fed to the input of the decoder 185. The decoder 185 decodes the spool length code and generates one from its outputs a high potential arriving at the corresponding inputs of the elements And 189-191. For definiteness, let us assume that the high potential from the output of the decoder 185 will open the And 190 element at one input.

At the other input, the And element 190 will be closed until a pulse from the output 182 of the module 9 arrives at the synchronizing input 198 of the module 10.

The codes of the G2 parameter group of the spool parameters from the output 147 of the register 140 of the module 6 are sent to the information input 153 of the module 7 for generating call signals of the server database subroutine and fed to the information input of the register 150, where they are entered by the server clock from the input 144 of the module 6, delayed by the delay element 142 at the time of operation of the register 140 and coming from the output 149 of the module 6 to the synchronizing input 154 of the module 7.

The same pulse from the input 154 of the module 7 is delayed by the delay element 152 for the time the parameters of the spool of the G2 group are entered into the register 150 and from the output 33 of the system it enters the input of the second channel of the database server interrupt.

With the arrival of this impulse, the server polls its information inputs and picks up the parameter codes of the G2 spool from the information output 28 of the system and returns from its database the information in the system input 18 of the system as a damping coefficient code for the spool pair.

The code for damping the spool pair read from the server database from the information input 18 of the system goes to the information input 165 of the register 160 of the module 8 for identifying the state of the spool pair, where it is entered by the synchronizing pulse of the server, which is input to the system 23.

The damping coefficient code of the spool pair from the output of register 160 goes to the input 168 of the comparator 161, to the other input 167 of which a precautionary state threshold code is output from the output 64 of module 1. By the synchronizing pulse of the server from the input 166 of module 8, delayed by the delay element 163 for the time the code was entered damping coefficient in the register 160, the comparator 161 compares the codes received at its inputs.

If the current damping coefficient of the spool pair, read from the server database and received from the register 160 to the input 168 of the comparator 161, is less than the pre-failure state threshold set by the system user and received at the input 167 of the comparator 161 from the output 64 of the module 1, then the output of the 170 comparator 161 a signal is generated.

This signal, firstly, from the output 170 of the comparator 161 goes to the signal output 35 of the system, from where the signal "Spool pair is in working condition" is issued to the user's workstation.

Secondly, the signal from the output 170 of the comparator 161 passes the OR element 162 and enters the installation input of the register 160, resets its contents to zero and thereby prepares it for a new operation cycle.

Thirdly, the signal from the output 170 of the comparator 161 is supplied:

- to the installation input 51 of module 1, the OR element 46 passes and enters the installation input of the register 40, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 98 of module 3, the OR element 90 passes and enters the installation input of the register 86, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 110 of module 4, the OR element 106 passes and enters the installation input of the register 105, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 135 of module 5, the OR element 127 passes and enters the installation input of the register 123, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 145 of module 6, the OR element 141 passes and enters the installation input of the register 140, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 155 of module 7, the OR element 151 passes and enters the installation input of the register 150, resets its contents to zero, thereby preparing it for a new operation cycle.

If the current damping coefficient of the spool pair, read from the server database and received from the register 160 to the input 168 of the comparator 161, is greater than or equal to the threshold of the precautionary state set by the user of the system and received at the input 167 of the comparator 161 from the output 64 of module 1, then a signal is generated already at the output 169 of the comparator 161.

This signal, firstly, from the output 169 of the comparator 161 goes to the signal output 36 of the system, from where the signal "Spool pair is in precautionary state" is issued to the user's workstation.

Secondly, the same signal from the output 169 of the comparator 161 passes the OR element 162 and enters the installation input of the register 160, resets its contents to zero and thereby prepares it for a new operation cycle.

Thirdly, the same signal from the output 169 of the comparator 161 is fed to the synchronizing input 180 of the module 9 for selecting the base address of the relations of the speed of sound in the material of the spool body to the length of the spool and passes through the And 175 element open through one input to the read input of a fixed cell of a permanent storage device (ROM) 174.

In a fixed cell of the ROM 174, the code of the base address of the relations of sound speed in the material of the spool body to the length of the spool is stored, starting with which the codes of the relations of the speed of sound in the material of the body of the spool to the material of the spool to the length of the spool are stored.

The code of the base address of the ratios of sound speed in the material of the spool to the length of the spool from the output 181 of the module 9, read from the ROM 174, is sent to the information input 197 of the module 10 for generating signals for reading the ratios of the speed of sound in the material of the body of the spool to the length of the spool and goes to one information input of the adder 187 .

The clock pulse from the input 180 of module 9, delayed by the delay element 178 for reading the contents of the fixed cell ROM 174, from the output 182 of the module 9 is supplied to the clock input 198 of the module 10 and passes through the element And 190, which is open through one input, to the read input of the fixed memory cell devices (ROM) 186. In a fixed cell of the ROM 186 is stored the offset code of the relative read address of the ratio of the speed of sound in the material of the valve body to the length of the valve relative to the base address the speed of sound in the material of the valve body to the length of the valve.

The offset code of the relative reading address of the ratio of the speed of sound in the material of the spool body to the length of the spool, read from the ROM 186, is fed to one information input of the adder 187, on the other information input of which is already the code of the base address of the relations of the speed of sound in the material of the body of the spool to the length of the spool, adopted on input 197 of module 10 from output 181 of module 9.

According to the clock pulse from the input 198 of the module 10, delayed by the delay element 193 for the time of reading the fixed cell of the ROM 186, in the adder 187, the relative address of the reading of the ratio of the speed of sound in the material of the valve body to the length of the valve is formed. This address from the output of the adder 187 goes to the information input of the register 188, where it is entered by the synchronizing pulse from the output of the delay element 193, delayed by the delay element 194 for the duration of the operation of the adder 187.

The same pulse from the output of the delay element 194 is delayed by the delay element 195 for the response time of the register 188 and from the output of the system 34 is fed to the input of the first channel of the server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 27 of the system, and issuing the read spool parameters to the information input 19 of the system.

The code for the ratio of the speed of sound in the material of the valve body to the length of the valve from the information input 19 of the system, read from the server’s database, enters the information input 208 of register 204 of the ultrasonic vibration frequency identification module 11, where it is entered by the server’s synchronizing pulse supplied to the system input 24.

This code from the output of register 204 is supplied to the information input of the shift register 205 and is shifted to the right by one bit according to the server synchronizing pulse supplied to the synchronization input of the shift register 205 from the synchronizing input 209 of module 11 after a delay by the delay element 206 for the response time of the register 204.

The code of the frequency of ultrasonic vibrations generated in the shift register 205 from the information output 211 of the module 11 is supplied both to the information output of the system 29, from where it is output to the user's workstation and to the information input 231 of the ultrasonic vibration power identification module 12.

The synchronizing pulse from the output of the delay element 206, delayed by the delay element 207 for the duration of the shift register 205, is output from the output 212 of the module 11 both to the signal output 38 of the system, from where the signal “Frequency of ultrasonic vibrations” is output to the user workstation, and to the synchronization input 234 modules 12.

According to the synchronizing pulse at the input 234 of module 12, the code of the frequency of ultrasonic vibrations supplied from the input 231 of the module 12 to one input of the multiplier 215 is multiplied with the code of the amplitude of free vibrations of the spool supplied to its other input from the information output 65 of module 1. The result of the multiplication is fed to the inputs multiplier 216.

According to the clock pulse at the input 234 of the module 12, delayed by the delay element 222 for the time of operation of the multiplier 215, the codes of the multiplier 216 are multiplied. The result of the multiplication is fed to one input of the multiplier 217, to the other input of which a frequency code of ultrasonic vibrations is supplied from the information input 231 of module 12.

According to the clock pulse from the output of the delay element 222, delayed by the delay element 223 for the time of operation of the multiplier 216, the codes of the multiplier 217 are multiplied. The result of the multiplication is fed to one input of the multiplier 218, at the other input of which is the mass code of the valve body, received at the input 232 of module 12 from the output 113 of module 4.

According to the clock pulse from the output of the delay element 223, delayed by the delay element 224 for the time of operation of the multiplier 217, the codes of the multiplier 218 are multiplied. The result of the multiplication is fed to one input of the multiplier 219, to the other input of which the code of the coefficient of increase in power is supplied from the output 66 of module 1.

According to the clock pulse from the output of the delay element 224, delayed by the delay element 225 by the time of operation of the multiplier 218, the codes of the multiplier 219 are multiplied. The result of the multiplication is fed to the input of the shift register 220.

According to the synchronizing pulse from the output of the delay element 225, delayed by the delay element 226 for the time of operation of the multiplier 219, the code in the shift register 220 is shifted to the left by one bit and is fed to the input of the shift register 221.

According to the clock pulse from the output of the delay element 226 delayed by the delay element 227 by the time of the code shift in the shift register 220, the code in the shift register 221 is shifted to the left by one bit.

The result of the shift in the form of a code of the power of ultrasonic vibrations goes to the output 236 of the module 12 and from the information output 30 of the system is issued to the workstation of the user of the system.

The issuance of the ultrasonic vibrations power code system to the user’s workstation is accompanied by a signal that is delayed by the delay element 228 from the output of the delay element 228 for the duration of the shift register 221, and the signal “Ultrasonic vibrations power” is output from the output 237 of the module 12, which is issued from the signal output 37 of the systems to the user's workstation.

The same pulse from the output of the delay element 228 is supplied to the installation inputs of the shift registers 220 and 221, resets their contents to zero, thereby preparing them for a new cycle of operation.

In addition, the signal from the output 237 of the module 12 is supplied:

- to the installation input 52 of module 1, the OR element 46 passes and enters the installation input of the register 40, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 99 of module 3, the OR element 90 passes and enters the installation input of the register 86, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 111 of module 4, the OR element 106 passes and enters the installation input of the register 105, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 136 of module 5, the OR element 127 passes and enters the installation input of the register 123, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 146 of module 6, the OR element 141 passes and enters the installation input of the register 140, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 156 of module 7, the OR element 151 passes and enters the installation input of the register 150, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 199 of the module 10 and enters the installation input of the register 188, resets its contents to zero, thereby preparing it for a new operation cycle;

- to the installation input 210 of module 11 and enters the installation inputs of the registers 204 and 205, resets their contents to zero, thereby preparing them for a new cycle of work.

Thus, the introduction of new nodes and modules and new structural connections has significantly improved system performance by eliminating data retrieval across the entire system server database.

Information sources

1. US Patent No. 5136708, M.C. G06F 15/16, 1992.

2. US Patent No. 5129083, M.C. G06F 12/00, 15/40, 1992 (prototype).

3. Uryavin S.P., Konyaev E.A. Monitoring the state of the spool pairs of the gas turbine control equipment by vibration diagnostic methods. / Civil aviation at the present stage of development of science, technology and society: A collection of abstracts of the participants of the International scientific and technical conference dedicated to the 40th anniversary of the MSTU GA (May 26, 20011). - Moscow: RIO MSTU GA, p. 45.

4. Konyaev EA, Uryavin S.P. Development of a method for ensuring the reliability of spool pairs of gas turbine engine control equipment. - Scientific Bulletin of MSTU GA, 2009, No. 147, S.125-128.

Claims (1)

A system for preventing sticking of spool pairs of fuel control equipment of aircraft gas turbine engines by means of ultrasonic excitation of the housing, comprising a module for identifying the base address of the aircraft engine, the information input of which is the first information input of the system designed to receive the request codogram from the workstation of the user of the system, synchronizing the input of the module for identifying the base address of the aircraft engine is the first synchronizing input of the system, p intended for receiving synchronization signals of entering the request codogram from the workstation of the system user into the aircraft engine base address identification module, the controller-pump relative address formation module, the first and second information inputs of which are connected to the first and second information outputs of the aircraft engine base address identification module, respectively, the input of the module for generating the relative address of the pump controller is connected to the synchronizing the output of the aircraft engine base address identification module, the spool housing parameter readout signal generation module, one information input of which is connected to the information output of the pump controller controller relative address formation module, and the spool housing parameter readout signal formation module, the output module is connected to the third information output of the identification module base address of the aircraft engine, synchronizing the input of the module for generating parameters reading signals the valve body is connected to the synchronizing output of the module for generating the relative address of the pump-controller, one information output of the module for generating signals for reading the parameters of the valve body is the first address output of the system designed to provide the address of the valve body to the address input of the database server, and the synchronizing output of the module for generating read signals parameters of the spool housing is the first synchronizing output of the system, designed to issue controlled signals by reading the spool housing parameters to the input of the first channel server interrupt channel, the spool housing registration module, the information input of which is the second information input of the system, designed to receive the spool housing parameter codes read from the server database, synchronizing the input of the spool housing parameters registration module is the second synchronizing input of the system, intended for receiving signals of entering codes of the parameters of the valve body parameters, read and the server database, into the valve body parameter registration module, the valve parameter readout signal generation module, one information input of which is connected to another information output of the valve body parameter readout signal generation module, and the other information input of the valve body readout signal generation module, is connected to the fourth information output aircraft engine base address identification module, clock input of read signal generation module the spool parameters is connected to the synchronizing output of the spool housing parameter registration module, the information output of the spool parameter reading signal generation module is the second address output of the system designed to provide the spool address to the database server address input, and the synchronizing output of the spool parameter reading signal generation module is the second system output designed to provide control signals for reading spool parameters and the input of the first channel of the database server interruption, the spool parameter registration module, the information input of which is the third information input of the system, designed to receive the spool parameter codes read from the server database, the synchronizing input of the spool parameter registration module is the third synchronization input of the system, receiving signals of entering the spool parameter codes read from the server database into the spool parameter registration module, the ide module the specification of the power of ultrasonic vibrations of the valve body, the first and second information inputs of which are connected to the fifth and sixth information outputs of the identification module of the base address of the aircraft engine, respectively, the third information input of the module for identifying the power of ultrasonic vibrations of the valve body is connected to one information output of the module for registering the parameters of the valve body, information output the module for identifying the power of ultrasonic vibrations of the valve body is the first information output of the system intended for issuing a power code of ultrasonic vibrations of the spool housing to the workstation of the user of the system, the synchronizing output of the module for identifying the power of ultrasonic vibrations of the spool housing is the first signal output of the system designed to provide a signal for identifying the power code of ultrasonic vibrations of the spool housing system user, characterized in that it contains a module call signals of the server database subroutine, the information input of which is connected to one information output of the valve parameter registration module, the synchronizing input of the server database subroutine signal generation module is connected to the synchronizing output of the valve parameter registration module, the information output of the server database subroutine signal generation module is the second information output of the system, intended for issuing fuel viscosity codes in the vicinity spool springs, fuel density, sediment mass, friction area, gap between spool and bushing, spring stiffness and spool mass to the database server information input, and the synchronizing output of the server database subroutine signal generation module is the third system output intended for issuing control signals of the server database subroutine call to the input of the second channel of the database server interrupt, module for identifying the state of the spool pair, one information whose input is the fourth information input of the system, intended for receiving codes of damping coefficients of the spool pair read from the server database, another information input of the spool pair identification module is connected to the seventh information output of the aircraft engine base address identification module, synchronizing the input of the spool pair identification module is the fourth synchronizing input of the system, designed to receive signals entering codes to damping coefficients of the spool pair, read from the server database, to the spool pair identification module, one synchronizing output of the spool pair identification module is the second signal output of the system, designed to provide a signal of identification of the working state of the spool pair to the workstation of the system user, and connected with one installation input of the aircraft engine base address identification module, with one installation input of the module f of composing signals for reading the parameters of the valve body, with one installation input of the module for registering the parameters of the valve body, with one installation input of the module for generating signals for reading the parameters of the valve, with one installation input of the module for registering parameters of the valve, with one installation input of the module for generating signals for calling the server database subroutine, another synchronizing output of the spool pair identification module is the third signal output of the system, designed a signal for identifying the pre-failure state of the spool pair to the workstation of the user of the system, a module for selecting the base address of the relationship of the speed of sound in the material of the spool body to the length of the spool, the information input of which is connected to another information output of the module for registering parameters of the spool body, and the synchronizing input of the selection module the base address of the relationship of the speed of sound in the material of the valve body to the length of the valve is connected to another synchronizing an ode to the spool pair state identification module, a signal generation module for reading the ratio of sound velocity in the spool housing material to the spool length, one information input of which is connected to the information output of the selection module of the base address of the sound velocity in the spool housing material to the spool length, another information input of the formation module read signals of the ratio of the speed of sound in the material of the valve body to the length of the valve connected to another information output of the module registering the parameters of the spool, the clock input of the module for generating read signals of the ratio of the speed of sound in the material of the spool to the length of the spool is connected to the synchronizing output of the module for selecting the base address of the relations of the speed of sound in the material of the body of the spool to the length of the spool, the information output of the module for generating signals for reading the signals of the ratio of sound speed in the material the spool housing to the length of the spool is the third address output of the system, designed to provide the address of the relationship the sound velocity in the material of the valve body to the length of the valve to the address input of the database server, and the synchronizing output of the module for generating signals for reading the ratio of sound speed in the material of the valve body to the length of the valve is the fourth synchronizing output of the system designed to provide control signals for reading the ratio of the speed of sound in the material the spool housing to the length of the spool at the input of the first channel of the database server interrupt the spool housing, the information input of which is the fifth information input of the system, designed to receive codes of the ratios of the speed of sound in the material of the spool housing to the length of the spool read from the server database, the synchronizing input of the module for identifying the frequency of ultrasonic vibrations of the spool housing is the fifth synchronizing input of the system, designed to receiving signals of entering codes of the relations of the speed of sound in the material of the valve body to the length of the valve, read from the server database , to the module for identifying the frequency of ultrasonic vibrations of the valve body, the information output of the module for identifying the frequency of ultrasonic vibrations of the valve body is the third information output of the system, intended for issuing frequency codes of ultrasonic vibrations of the valve body to the workstation of the user of the system, and is connected to the fourth information input of the power identification module ultrasonic vibrations of the valve body, and the synchronizing output of the identification module is often You of the ultrasonic vibrations of the spool housing is the fourth signal output of the system, designed to provide an identification signal for the frequency code of ultrasonic vibrations of the spool housing to the workstation of the user of the system, and is connected to the synchronizing input of the module for identifying the power of ultrasonic vibrations of the valve body, while the synchronizing output of the ultrasonic power identification module oscillations of the valve body is connected to another installation input of the identification module and the base address of the aircraft engine, with a different installation input of the module for generating signals for reading parameters of the valve body, with a different installation input for the module for registering parameters for the valve body, with another installation input for the module for reading parameters for the valve, with another installation input for the module for registering parameters of the valve the input of the signal generation module of the server database subroutine call, with the installation input of the ultrasonic frequency identification module oscillations of the valve body and with the installation input of the module for generating signals for reading the ratio of the speed of sound in the material of the valve body to the length of the valve.

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