KR102273610B1 - Rotating Body Vibration Processing Board, Rotating Body Vibration Monitoring System, and Rotating Body Vibration Monitoring Method - Google Patents

Abstract

The present invention relates to an integrated monitoring system for blade-shaft assembly rotating body vibration based on socket communication and firmware, which comprises: a rotating body vibration signal processing device including a blade vibration signal processing board for receiving a blade vibration signal from a blade vibration sensor system to detect blade vibration and a shaft vibration signal processing unit for receiving a rotating shaft vibration signal from a shaft vibration sensor system to detect shaft vibration; and a rotating body vibration integrated calculation device for monitoring vibration of a rotating body in real time using data received through a socket communication interface from the rotating body vibration signal processing device. Accordingly, the monitoring performance can be significantly improved by applying various noncontact vibration sensors of casing and rotating shaft support bearings to a blade rotating body, such as a gas turbine compressor, which is a key rotating body facility for thermal power generation.

Description

Rotating Body Vibration Signal Processing Board, Rotating Body Vibration Signal Monitoring System, and Rotating Body Vibration Monitoring Method {Rotating Body Vibration Processing Board, Rotating Body Vibration Monitoring System, and Rotating Body Vibration Monitoring Method}

It relates to a rotating body vibration signal processing board, a rotating body vibration signal monitoring system, and a rotating body vibration monitoring method, and more specifically, a blade that monitors the vibration of blade and shaft assembly based on firmware applied with PGA (Field Programmable Gate Array)- It relates to a shaft vibration signal processing board for integrated monitoring of shaft assembly rotational vibration.

Electricity is produced by converting the flow energy of the fluid into rotational energy in the rotating blades of the turbine and converting it into electrical energy in the generator. For reliable operation of a gas turbine engine for power generation, it is necessary to operate to minimize excessive resonance amplitude in the rotating blades of each stage along with excessive vibration of the rotating shaft.

The rotating shaft and rotating blade generate high vibration as they pass through the main engine order. In particular, even under normal operating conditions, high vibration amplitude or displacement is generated in the blade depending on the output.

The failure of the rotating blade, which is the basic element responsible for fluid fluctuation and rotational force inside the casing of a gas turbine or steam turbine operated in the electric power system, accounts for 48% of all equipment failures. However, only the axis element monitoring system, which accounts for 12%, is monitoring the rotating body equipment. That is, with the shaft vibration monitoring technology, only the initial damage related to shaft rubbing and bearing damage, which accounts for 29% of rotational body failures, can be recognized.

The crack failure of the rotating blade, which accounts for 68% of the failure of the rotating body, occurs very frequently, but cannot be recognized until the mass is lost. Therefore, the current rotating body vibration monitoring system needs to monitor not only the shaft vibration but also the rotating blade vibration at the same time. there is

Shaft vibration monitoring technology requires data processing capability with time resolution of several ms to several μs, whereas rotary blade vibration monitoring technology requires large data processing capability with time resolution of several ns to several tens of ns. In particular, it is necessary to monitor the rotating body by processing the rotational blade vibration signal as well as processing the existing shaft vibration signal through a dedicated board that processes the shaft vibration signal and the blade vibration signal, respectively, and components integrating them.

US 10-1829134 B1 US 10-1041016 B1

The present invention is derived from this technical background, and in order to monitor the rotating body by processing the shaft vibration signal as well as processing the rotation blade vibration signal, a high-speed signal processing digital signal processor (Digital Signal Processor) and FPGA (Digital Signal Processor) It consists of a rotating blade vibration signal processing board with built-in FPGA) and a real-time axial vibration signal processing board. Steam turbine, gas turbine and compressor operated in the power system are implemented to enable simultaneous signal processing through the phase-locked signal processing board. The purpose is to propose this rotating body vibration signal processing device and blade-shaft assembly rotating body vibration integrated monitoring system that can process high-speed signal processing of shaft vibration and blade vibration and transmit large-capacity data through socket-type communication technology.

In addition, by devising a system that processes and monitors blade vibration and displacement by synchronizing and linking the rotation speed processing element for real-time monitoring of shaft vibration and operating factors such as the rotation speed and output of equipment, the steam turbine operated in the power system, It is intended to provide an integrated monitoring system for the vibration of the blade-shaft assembly rotating body that can simultaneously process and monitor the shaft vibration and blade vibration of gas turbine and compressor in real time.

In particular, one or more blade tip vibration sensors are installed in the casing during operation of the facility, and the tip timing algorithm that calculates the arrival time by merging the measured blade pulse signal with the high-speed clock signal and the rotation speed signal is implemented in FPGA (Field Programmable Gate Array). It is implemented based on the firmware applied to the operation data, and in connection with the generator output signal, which is the operation data, not only in transient operation modes such as start/stop of rotating equipment, but also in the normal output operation condition, the static displacement and vibration amplitude of the rotating blade are synchronized and integrated with the shaft vibration. It is intended to provide an integrated monitoring system for vibration of the blade-shaft assembly rotating body that can be monitored.

In particular, for the transient and normal operating conditions, a blade crack failure monitoring factor is devised based on the blade tip timing data, and the designed fault factors are output based on the operating data. An object of the present invention is to provide an integrated monitoring system for vibration of a blade-shaft assembly rotating body that can simultaneously monitor blades in real time.

The present invention for achieving the above object includes the following configuration.

The embodiment provides a blade-shaft assembly rotating body vibration signal processing board, the vibration signal processing board comprising: an axial vibration signal input unit for receiving an axial vibration detection signal from an axial vibration sensor system of a rotating shaft support bearing; an axial oscillation phase-locked signal detector for detecting a phase-locked signal; and a shaft vibration signal processing module for receiving the phase synchronization information from the phase synchronization signal detector and processing the shaft vibration detection signal of the rotating body by synchronizing the phase synchronization signal with the blade vibration signal processing board.

In addition, the vibration signal processing board according to the embodiment filters the shaft vibration detection signal input to the shaft vibration signal input unit into a set band, extracts only a desired band signal, amplifies it to a predetermined level, and stabilizes the shaft vibration signal to be electrically stabilized device further.

In addition, the vibration signal processing board according to the embodiment communicates with the rotating body vibration integrated calculation device in a socket communication method and transmits the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device. It further includes a communication module.

In addition, the axial vibration communication module of the vibration signal processing board according to the embodiment applies an embedded core (Arm Core) for controlling peripheral devices and transmits it to the rotating body vibration integrated computing device through a socket communication interface.

In addition, the axial vibration communication module of the vibration signal processing board according to the embodiment is a socket communication method for improving communication speed and overload with harmonic component data and raw data of axial vibration processed by the axial vibration signal processing module It is transmitted to the rotating body vibration integrated computing device through the Internet port.

In addition, the axial vibration signal processing module of the vibration signal processing board according to the embodiment is included in a digital signal processor for high-speed signal processing.

In addition, the shaft vibration signal processing module of the vibration signal processing board according to the embodiment processes and analyzes data in real time by calculating based on the rotation speed of the blade-shaft assembly rotating body.

In addition, the axial vibration phase synchronization signal detector of the vibration signal processing board according to the embodiment transmits and receives a phase synchronization logic signal through a Back Plain board and counts the number of revolutions to determine the number of revolutions data, phase synchronization It detects the signal and provides the information of the corresponding rotation speed to the shaft vibration signal processing module.

In addition, the shaft vibration signal processing module of the vibration signal processing board according to the embodiment measures the peak signal from the shaft vibration sensor system input to the shaft vibration signal input unit and processes the shaft vibration in the rotating shaft support bearing based on firmware do.

In addition, the shaft vibration signal processing module of the vibration signal processing board according to the embodiment performs shaft vibration alarm data processing, shaft vibration waveform data calculation, shaft vibration order component and GAP calculation in DSP, and integrates rotational vibration through a network Send data to the computing device.

In addition, the shaft vibration sensor system of the vibration signal processing board according to the embodiment installs an eddy current vibration sensor with two non-contact vibration sensors at 90* intervals at each vibration measurement position of the rotation shaft support bearing to measure the vibration displacement with respect to the rotation shaft. measure

According to another embodiment, there is provided a shaft vibration signal processing method for integrated monitoring of the blade-shaft assembly rotating body vibration, and this shaft vibration signal processing method includes receiving a shaft vibration detection signal from the shaft vibration sensor system of the rotating shaft support bearing part step; detecting a phase lock signal; Synchronizing the blade vibration signal processing board and the phase synchronization signal by receiving the phase synchronization information from the phase synchronization signal detector; and processing the shaft vibration detection signal of the rotating body.

In addition, the method for processing an axial vibration signal according to another embodiment includes: filtering an axial vibration detection signal input to an axial vibration signal input unit into a set band; The method further includes extracting only a desired band signal, amplifying it to a predetermined level, and electrically stabilizing the signal.

In addition, the shaft vibration signal processing method according to another embodiment comprises the steps of communicating with a rotating body vibration integrated computing device in a socket (Socket) communication method; And it further comprises the step of transmitting the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device.

In addition, the step of communicating with the rotating body vibration integrated computing device in the socket communication method of the axial vibration signal processing method according to another embodiment applies an embedded core (Arm Core) for controlling peripheral devices and through a socket communication interface and transmitting to the rotating body vibration integrated computing device.

In addition, in the shaft vibration signal processing method according to another embodiment, the step of transmitting the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device includes harmonics of the shaft vibration processed by the shaft vibration signal processing module It includes the step of transmitting the component data and raw data to the rotating body vibration integrated computing device through the Internet port in a socket communication method that improves communication speed and overload.

In addition, in the method for processing an axial vibration signal according to another embodiment, the axial vibration signal processing module is included in a digital signal processor for high-speed signal processing.

In addition, the shaft vibration signal processing method according to another embodiment further includes the step of processing and analyzing data in real time by calculating based on the number of rotations of the blade-shaft assembly rotating body.

In addition, in the shaft vibration signal processing method according to another embodiment, the shaft vibration phase synchronization signal detector transmits/receives a phase synchronization logic signal through a back plain board and counts the rotation speed to determine the rotation speed data ; and providing, by the shaft vibration phase lock signal detector, information on a corresponding rotation speed to the shaft vibration signal processing module by detecting the phase lock signal.

In addition, in the axial vibration signal processing method according to another embodiment, the processing of the axial vibration detection signal of the rotating body includes: measuring a peak signal from the axial vibration sensor system input to the axial vibration signal input unit; and signal processing the shaft vibration in the rotating shaft support bearing based on firmware.

In addition, the step of processing the shaft vibration detection signal of the rotating body of the shaft vibration signal processing method according to another embodiment includes: shaft vibration alarm data processing in DSP, shaft vibration waveform data calculation, shaft vibration order component and GAP calculation step; and transmitting data to the rotating body vibration integrated computing device through the network.

In addition, in the shaft vibration signal processing method according to another embodiment, the shaft vibration sensor system installs an eddy current vibration sensor with two non-contact vibration sensors at an interval of 90* at each vibration measurement position of the rotation shaft support bearing, The method further includes measuring the vibrational displacement.

According to another embodiment, the blade-shaft assembly provides a rotating body vibration signal monitoring system including a rotating body vibration signal processing board, and the vibration signal processing board of the rotating body vibration signal monitoring system includes the axis of the rotating shaft support bearing part. a shaft vibration signal input unit for receiving a shaft vibration detection signal from the vibration sensor system; an axial oscillation phase-locked signal detector for detecting a phase-locked signal; and a shaft vibration signal processing module for receiving the phase synchronization information from the phase synchronization signal detector and processing the shaft vibration detection signal of the rotating body by synchronizing the phase synchronization signal with the blade vibration signal processing board.

The rotating body vibration signal monitoring system further includes a shaft vibration signal stabilizing device that filters the shaft vibration detection signal input to the shaft vibration signal input unit into a set band, extracts only a desired band signal, amplifies it to a predetermined level, and electrically stabilizes it. include

This rotating body vibration signal monitoring system communicates with the rotating body vibration integrated calculation device in a socket communication method and transmits the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device. include more

In this rotating body vibration signal monitoring system, the shaft vibration communication module applies an embedded core (Arm Core) for controlling peripheral devices and transmits it to the rotating body vibration integrated computing device through a socket communication interface.

In such a rotating body vibration signal monitoring system, the shaft vibration communication module transmits the harmonic component data and raw data of the shaft vibration processed by the shaft vibration signal processing module to the Internet using a socket communication method to improve communication speed and overload. It is transmitted to the rotating body vibration integrated computing device through the port.

The shaft vibration signal processing module of the rotating body vibration signal monitoring system is included in a digital signal processor for high-speed signal processing.

The shaft vibration signal processing module of this rotating body vibration signal monitoring system processes and analyzes data in real time by calculating based on the rotation speed of the blade-shaft assembly rotating body.

The shaft vibration phase synchronization signal detector of this rotating body vibration signal monitoring system transmits and receives a phase synchronization logic signal through a Back Plain board, counts the number of rotations, recognizes the rotation speed data, and detects a phase synchronization signal to provide the information of the corresponding rotation speed to the shaft vibration signal processing module.

The shaft vibration signal processing module of the rotational vibration signal monitoring system measures the peak signal from the shaft vibration sensor system input to the shaft vibration signal input unit and processes the shaft vibration in the rotating shaft support bearing as a firmware-based signal.

The shaft vibration signal processing module of this rotating body vibration signal monitoring system processes shaft vibration alarm data, calculates shaft vibration waveform data, calculates shaft vibration order components and GAP in DSP, and converts it to an integrated rotating body vibration calculation device through a network transmit data.

The shaft vibration sensor system of this rotating body vibration signal monitoring system measures the vibration displacement with respect to the rotation shaft by installing an eddy current vibration sensor with two non-contact vibration sensors at an interval of 90* at each vibration measurement position of the rotation shaft support bearing.

1 is a block diagram showing the configuration of a rotating body vibration integrated monitoring system according to an embodiment of the present invention;
2A to 2C are exemplary views for explaining a signal processing operation between a sensor unit and a signal processing device provided in a blade-shaft assembly rotating body according to an embodiment of the present invention;
3 is a block diagram showing the configuration of a blade vibration signal processing board according to an embodiment of the present invention;
4A and 4B are exemplary diagrams for explaining logic signal conversion and arrival time measurement;
5 is a data flow diagram of a blade vibration signal processing board according to an embodiment of the present invention;
6 is an exemplary diagram for explaining signal processing of a time-synchronized and phase-synchronized frame;
7 is a block diagram for explaining the operation of the axial vibration signal processing board according to an embodiment of the present invention;
8 is a data flow diagram in an axial vibration signal processing board according to an embodiment of the present invention;
9 is a flowchart illustrating a time synchronization and phase synchronization method according to an embodiment of the present invention.

It should be noted that the technical terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. In addition, the technical terms used in the present invention should be interpreted as meanings generally understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined in particular in the present invention, and excessively comprehensive It should not be construed in the meaning of a human being or in an excessively reduced meaning.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

Rotating body vibration integrated monitoring system according to an embodiment of the present invention is a system for processing and monitoring blade vibration and displacement by synchronizing and linking operating elements such as rotation speed processing element and equipment rotation speed and output for real-time monitoring It is possible to simultaneously process and monitor the shaft vibrations and blade vibrations of steam turbines, gas turbines and compressors operated in the power system in real time.

In particular, one or more blade tip vibration sensors are installed in the casing during operation of the facility, and the tip timing algorithm that calculates the arrival time by merging the measured blade pulse signal with the high-speed clock signal and the rotation speed signal is implemented in FPGA (Field Programmable Gate Array). It is implemented based on the firmware applied to the operation data, and in connection with the generator output signal, which is the operation data, it synchronizes and integrates the static displacement and vibration amplitude of the rotating blade with the shaft vibration not only in the operation mode with the start/stop of the rotating equipment but also under the normal output operation condition. can be monitored.

In addition, for the transient and normal operating conditions, the blade crack failure monitoring factor is output based on the blade tip timing data and the rotational shaft vibration and the rotational blade vibration of the rotating equipment are simultaneously monitored in real time according to the transient and normal operating conditions along with the output operation data. Simultaneous signal processing is possible through time synchronization and phase synchronization through NTP and phase synchronization signal generation board for signal processing.

1 is a block diagram showing the configuration of a rotating body vibration integrated monitoring system according to an embodiment of the present invention.

The rotating body vibration integrated monitoring system 700 according to an embodiment is a rotating body vibration signal processing device 600 for processing a signal input from the sensor unit 90 for generating a detection signal according to the rotation of the blade-shaft assembly rotating body ), a rotating body vibration integrated calculation device 400, and a power generation facility operation system linkage module 500, and these components are connected by a network.

Specifically, the rotating body vibration integrated monitoring system 700 receives the blade vibration signal from the blade vibration sensor system 91 through the blade vibration signal input unit 101, and processes the blade tip timing signal and the tip gap signal based on the FPGA firmware. The shaft vibration signal of the shaft vibration sensor system 93 including the blade vibration signal processing board 200 for processing and a non-contact vibration sensor applied to the rotation shaft support bearing is inputted through the shaft vibration signal input unit 103, and the shaft vibration A phase synchronization signal input unit 102 that provides a phase synchronization signal to the shaft vibration signal processing board 300 and the blade vibration signal processing board 200 and the shaft vibration signal processing board 300 for processing the rotation shaft vibration signal in real time. It includes a phase synchronization signal generation board, a rotating body vibration integrated calculation device 400 and a power generation facility operation system linkage module 500 .

2A to 2C are exemplary views for explaining a signal processing operation between a sensor unit and a signal processing device provided in a blade-shaft assembly rotating body according to an embodiment of the present invention.

2A is an exemplary view for explaining in detail a sensor unit provided in a rotating body according to an embodiment of the present invention.

The rotating body vibration signal processing apparatus 600 receives a vibration detection signal according to rotation from the sensor unit 90 including at least one non-contact sensor installed in the blade-shaft disk assembly of the turbine and the compressor of the power plant.

The rotating body vibration signal processing apparatus 600 includes a blade vibration signal input unit 101 , a phase synchronization signal input unit 102 , and an axial vibration signal input unit 103 , and the rotating body vibration signal processing apparatus 600 is a blade vibration signal and an integrated signal processing device including a processing board 200 , a phase synchronization signal input unit 102 , and an axial vibration signal processing board 300 .

The sensor unit 90 includes a blade vibration sensor system 91 , a phase-locked sensor system 92 , and an axial vibration sensor system 93 .

The blade vibration signal input unit 101 receives a blade vibration signal from the blade vibration sensor system 91 installed in the casing 13 of the rotating body.

In one embodiment, the blade vibration sensor system 91 as shown in Figure 2a may be implemented as at least one non-contact sensor installed in the casing 13 of the rotating body.

The blade vibration sensor system 91 drills one or more sensor holes in the circumferential direction of the casing 13 of the rotary body on the radial direction of the blade-shaft disk assembly with respect to the casing 13 of the rotary body 13 as shown in FIG. It is implemented by installing a non-contact sensor (eddy current, reluctance, capacitance or optical probe) for vibration measurement, and detects blade vibration.

In this embodiment, the blade vibration signal input unit 101 receives from the blade vibration sensor system 91 at least each rotating blade 12 of the blade-shaft disk assembly of the power plant turbine and compressor is installed in the casing 13 of the rotating body. A peak signal generated when passing through one or more non-contact sensors is received.

And the blade vibration signal processing board 200 measures the peak signal of the blade vibration sensor system 91 input to the blade vibration signal input unit 101 and processes the signal based on the firmware.

The phase synchronization sensor system 92 is installed in a circumferential direction spaced apart from the radial direction of the rotation shaft 10 in which a key home is installed.

2B is an exemplary view of a bearing structure for explaining an axial vibration sensor system of a rotating shaft according to an embodiment of the present invention.

The turbine and compressor blade-shaft disk assembly of the power plant has a structure in which a plurality of rotating blades 12 are installed on each disk 11 attached to the rotating shaft 10 as shown in FIG. 2A, and the rotating shaft 10 is a bearing as shown in FIG. 2B structure supported by

The shaft vibration sensor system 93 of the rotary shaft is equipped with a vibration displacement measuring system for the rotary shaft through the non-contact vibration sensor of the bearing, and two non-contact vibrations are installed at each vibration measurement position of the bearing at 90˚ intervals to measure the vibration of the rotary shaft. It is implemented by installing an eddy current vibration sensor as a sensor.

The axial vibration sensor system 93 includes at least one or more gap sensors. In addition, the axial vibration sensor system 93 may include an eddy current vibration sensor.

The shaft vibration signal processing board 300 measures the peak signal from the shaft vibration sensor system 93 input to the shaft vibration signal input unit 103 and processes the shaft vibration in the rotating shaft support bearing as a firmware-based signal.

2C is an exemplary diagram for explaining a linkage structure of an integrated signal processing apparatus according to an embodiment.

The shaft vibration signal processing board 300 and the blade vibration signal processing board 200 are synchronized to enable simultaneous signal processing and monitoring. At this time, as in FIG. 2c , the time and phase of the device axis vibration signal processing board 300 and the blade vibration signal processing board 200 composed of a separate processor and a network are generated as a phase synchronization signal input unit 102 , a phase synchronization signal It is implemented to enable simultaneous signal processing and monitoring by synchronizing the phase synchronization signal input from the board as a reference.

The phase-lock signal input unit 102 is implemented as a phase-lock signal generation board.

In one embodiment, the phase-lock signal input unit 102 is phase-locked so that the data of the plurality of blade vibration signal processing board 200 and the shaft vibration signal processing board 300 having an independent IP address can be phase-synchronized and obtained. Generates a logic signal.

The phase synchronization signal input unit 102 provides the phase synchronization signal through a back plane as shown in FIG. 2C .

In one embodiment, the phase synchronization signal input unit 102 processes the acquisition start signal (Start Bit) and the phase synchronization signal of the phase synchronization sensor system 92 as an AND condition, and only when both are generated, the phase synchronization signal Initiate the occurrence and acquisition of data. And when data is acquired, the phases of the discretized blade vibration data and the discretized shaft vibration data are synchronized based on the Frame (revolution counter data composed of 8 bytes) corresponding to each number of revolutions.

The turbine/compressor of the power plant operated by feeding into the domestic 60Hz power system uses a two-pole generator, so the system synchronous rotation speed of the rotating body equipment is 3,600RPM.

At this time, data acquisition is based on the frame for each rotation speed synchronized with the reference time of the NTP (Network Time Protocol) in the rotating body vibration integrated communication module 420 and the synchronization data of the blade vibration discretization data and the shaft vibration discretization data. signal processing.

In one embodiment, the rotating body vibration signal processing device 600 is the blade vibration signal input unit 101 receives the blade vibration signal from the blade vibration sensor system 91, FPGA (Field Programmable Gate Array) firmware-based blade The shaft vibration signal of the non-contact vibration sensor applied to the blade vibration signal processing board 200 that processes the tip timing signal processing and the tip gap signal, and the shaft vibration signal input unit 103 is the rotation shaft support bearing part of the shaft vibration sensor system 93 and a shaft vibration signal processing board 300 that receives the input and processes the rotation shaft vibration signal in real time.

3 is a block diagram illustrating the configuration of a blade vibration signal processing board according to an embodiment of the present invention.

Blade vibration signal processing board 200 is a blade vibration signal input unit 101 for receiving a sensor signal from the blade vibration sensor system 91, a phase synchronization signal input unit 102 for receiving a sensor signal from the phase synchronization sensor system 92 , a blade vibration signal stabilization device 210, a trigger voltage comparator 220 combined counter (Counter) generation circuit 230, A/D data converter 240 that converts the analog signal of the sensor signal into a high-speed digital signal ), the recognition and setting function unit 260 having a function of setting the signal acquisition conditions and method of the blade vibration signal processing board 200, separated by the input conditions of the phase synchronization signal detector 250 for detecting the shaft rotation signal, and the signal It includes a data collection and storage module 270 , a signal processing module 280 , and a blade vibration communication module 290 for performing data collection data storage buffer and sequence definition.

In one embodiment, the blade vibration signal input unit 101 is an output signal (charge, small voltage, optical signal) of the blade vibration sensor system 91 such as an eddy current sensor, a magnetic sensor, or an optical sensor. It includes a voltage divider that converts the signal to a stable basic analog signal, and a protection circuit that prevents disturbance signals and surges.

The blade vibration signal stabilization device 210 stabilizes the basic analog signal of the blade vibration signal input unit 101 through an amplification amplifier (PGA, Programmable Gain Amp) and an analog frequency filter (BPF, Band Pass Filter), and the stabilized signal is A /D is input to the data converter 240 . The A/D data converter 240 provides a trigger voltage comparator 220 to discretize data and simultaneously provides a stabilized blade vibration analog signal to the trigger voltage comparator 220 to secure time resolution by a high-speed clock, and each blade is a sensor in the trigger voltage comparator 220 The NTP reference time for the trigger time is measured and provided to the counter generating circuit 230 .

4A and 4B are exemplary diagrams for explaining logic signal conversion and arrival time measurement. Specifically, FIG. 4A is a configuration diagram of an arrival time signal generation and counter device, and FIG. 4B is an exemplary diagram illustrating a counter measurement structure.

As shown in Figure 4a, the trigger voltage comparator 220 receives the basic analog signal passing through the blade vibration signal input unit 101 as an input.

The trigger voltage level (Level) of the percentage (%) of the peak size of the analog sensor signal is set as the threshold voltage, and the rising signal and the falling signal of the input sensor signal are compared with the set threshold voltage in the trigger voltage comparator 220. The analog signal provided by the blade vibration signal stabilization device 210 is provided to the counter generating circuit 230 to maintain a high signal when a signal higher than the reference signal occurs and maintain it as a low signal when a low signal occurs. to convert it into a logic signal.

At this time, the NTP reference time of arrival of each blade is reflected and the reference clock of several hundred MHz or more is generated in the counter measurement logic of the FPGA for the arrival time of the sensor of the rotating blade, and each blade is processed with a time resolution of several ns to several tens of ns.

Then, the logic signal is converted into a timing signal for measuring the sensor arrival time of the rotating blade and is input to the FPGA firmware-based counter generation circuit 230 .

And according to the condition, the logic signal generated from the counter generation circuit 230, which is a logic conversion circuit, is provided to the counter measurement logic of the FPGA, and a clock generator is placed in the FPGA counter measurement logic to set the time resolution frequency The clock is synchronized with the counter result of each blade to precisely measure the cycle (timing measurement), and the arrival time of each blade is processed with time resolution, provided to the blade signal processing module 280, and the arrival time of each blade is calculated. do.

The A/D data converter 240 generates raw data by high-speed discretization (converting an analog signal into a digital signal) processing the stabilized analog signal of the blade vibration signal stabilization device 210 . At the same time, the analog signal of the phase synchronization signal input unit 102 is received, converted into digital data, and provided to the DA converter 221 through the DSP.

The counter data of the FPGA firmware-based counter generating circuit 230 of FIG. 3 and the raw data discretized from the A/D data converter 240 are received from the FPGA and a parallel processing thread is applied to continuously transfer data without interruption. A double buffer is designed in a large-capacity DDR RAM. And by applying interrupt generation and Linux kernel UIO (Linux Kernel UIO), etc., while writing the data acquired by the FPGA in the first buffer 0 (Buffer 0), the second buffer (Buffer 1) is synchronized by the number of revolutions in the previous FPGA. Write.

And the processed (Write) data is sent to the blade signal processing module 280, and when the write of buffer 0 (Buffer 0) is finished, the data of buffer 0 is sent, and the FPGA writes data to buffer 1 (Buffer1) in the meantime. Data processing is performed continuously.

It is counted as shown in FIGS. 4A and 4B, and by real-time buffering and decomposition with a reference clock of hundreds of MHz or more, the gap time difference between the blade and the blade is calculated with high precision of time resolution of several ns to calculate the tip timing of each blade.

In FIG. 3 , the counter 251 receives the phase-locked logic signal through the Back Plain board, counts the number of rotations, and provides it to the blade vibration phase-locked signal detector 250 .

The blade vibration phase synchronization signal detector 250 receives the rotation speed data provided from the counter 253 as an input, detects a phase synchronization signal, and provides synchronization information of the rotation speed to the blade signal processing module 280 .

That is, the blade vibration phase synchronization signal detector 250 transmits a phase synchronization logic signal through a back plane (Back Plain) board. The blade vibration phase lock signal detector 250 receives the phase lock logic signal to count the number of rotations, and receives the provided rotation speed data as an input to detect the phase lock signal. And it provides the information of the rotation speed to the blade signal processing module 280 .

Recognition and setting function unit 260 is responsible for the control necessary for acquiring various signals of the blade vibration signal processing device (600). The recognition and setting function unit 260 generates and recognizes a code according to measurement elements such as arrival time, gap data, and raw data to generate and recognize a measurement element and a unique code for signal processing. In one embodiment, the recognition and setting function unit 260 is signal processing to the blade vibration signal stabilization device 210, the trigger voltage comparator 220, the counter generating circuit 230, and the A/D data converter 240 Assign the code and set the acquisition environment. In particular, it receives NTP reference time and acquisition start signal (Start Bit) and shares NTP reference time information.

The data collection and storage module 270 separates the signal processing conditions such as the counter recognition method and the raw data acquisition method in the recognition and setting function unit 260 to separate the data collection method and the storage sequence to collect and store sensor data in the buffer do.

In one embodiment, the discrete signal converted through the A/D data converter 240 is transferred to the FPGA at high speed, and data is collected and stored in a high-speed, large-capacity D-Dial memory (DDR RAM of at least 1GByte or more) to prevent loss of discrete data. The module 270 is applied to temporarily store data.

The blade signal processing module 280 is tipped through a digital signal processor for high-speed signal processing with the time resolution result of the arrival time of each blade provided to the counter measurement logic 231 of the FPGA. The timing analysis unit 281, the peak value extraction unit 282, and the digital filter 283 process the signals, and through the socket communication interface in the blade vibration communication module 290 in the CPU, the upper system, the rotating body vibration integrated computing device (400).

The tip timing analyzer 281 receives the result value of the counter generating circuit 230 . The arrival time of the rotating blade may be calculated by receiving the tip timing data of each arrival time calculated in real time. The tip timing analysis unit 281 receives the real-time measurement tip timing data of each blade that is phase-synchronized by the number of rotations provided by the counter measurement logic 231 of the FPGA, and calculates the arrival time of each rotation blade.

The peak value extraction unit 282 recognizes the raw data from the A/D data converter 240 and in each rotation through the blade vibration phase synchronization signal detector 250 according to the number of blades set in the recognition and setting function unit 260 . For each blade, the peak value is extracted.

The digital filter 283 uses the raw data of the A/D data converter 240 to change the sampling and apply the digital filter 283 so as to analyze the number of blade rotations and the harmonics and asynchronous vibration components of the rotation speed to apply the blade vibration It supports to perform characteristic analysis function.

The blade vibration communication module 290 applies a high-speed CPU for controlling a communication interface and peripheral devices in order to transmit large-capacity data processed by the blade signal processing module 280 . The blade vibration communication module 290 is separated by a socket communication method and simultaneously transmits it to the upper system through the Internet port in a structure to improve communication speed and overload.

Socket 1 is for setting the blade vibration board environment, and is a dedicated socket connected to the recognition and setting function unit 260 , and transmits the system setting contents along with time synchronization with the upper system and the rotating body vibration integrated computing device 400 .

The socket 2 is connected to the tip timing analyzer 281 and communicates with the sensor data for transmitting the measured arrival time (Tip-Timing) data.

The socket 3 is connected to the peak value extraction unit 282 and communicates with the blade gap peak voltage data among the sensor data.

The socket 4 is connected to the digital filter 283 and communicates by transmitting raw data and digital filter (multi-frequency filter) processed data among sensor data.

Socket n is an extra socket, which is an extra socket provided to transmit communication overload or additional data.

5 is a data flow diagram of a blade vibration signal processing board according to an embodiment of the present invention.

In one embodiment, the blade vibration signal processing board 200 is connected to the rotating body vibration integrated calculation device 400 , and is mounted on the rotating body vibration signal processing device 600 .

The environment setting module 410 in the rotating body vibration integrated calculation device 400 generates a reference time in the NTP (S10).

And transmit the reference time through the socket communication of the rotating body vibration integrated communication module 420 (S20) and each blade vibration signal processing board 200 and the shaft vibration signal processing board 300 having an independent IP address network A reference time is received through (S30).

And when the NTP reference time is synchronized in the blade vibration signal processing board 200 and the shaft vibration signal processing board 300 (S40), the data acquisition start signal from the environment setting module 410 of the rotating body vibration integrated computing device 400 In Start Bit is generated (S50), and transmitted to each blade vibration signal processing board 200 and the shaft vibration signal processing board 300 having an IP address through the network.

Then, the phase synchronization signal input unit 102 shares the data acquisition start signal (Start Bit) through the Back Plain board, and when the NTP standard time synchronization (S40) and AND condition are satisfied, the signal from the phase synchronization sensor is received. A phase-locked logic signal is generated (S70).

And when the phase synchronization signal is output through the Back Plain board (S80), the phase synchronization signal is received from the blade vibration signal processing board 200 and the counter 251 counts the number of revolutions (S90).

Afterwards, when the phase synchronization signal is detected in the blade vibration phase synchronization signal detector 250 (S100), the blade signal processing module 280 through the phase synchronization information for each number of rotations (S110) as shown in FIG. 6 (S110) The counter measurement logic of the FPGA ( 231) and FPGA buffering of large-capacity discretized data are input by synchronizing the phases by rotation speed with NTP reference time.

6 is an exemplary diagram for explaining signal processing of a time-synchronized and phase-synchronized frame.

Then, the blade signal processing module 280 calculates the rotation waveform and the blade waveform data processing (S120) in the DSP, the tip gap calculation for each blade (S130), and the arrival time for each blade (S140) and calculates the data for the rotational vibration integrated calculation Data is transmitted to the device 400 through the network (S150).

In the rotating body vibration integrated calculation device 400, the reference time of the reference time transmission (S20) generated in the NTP (S10) is aligned with the reference time for each data and the characteristic factor extraction (S160) is performed. After aligning the reference time for each data, the characteristic factors for monitoring are extracted, and the blade vibration monitoring of the rotating body is performed in real time (S170) and stored in the database (S180).

7 is a block diagram for explaining the operation of the axial vibration signal processing board according to an embodiment of the present invention.

The shaft vibration signal processing board 300 is included as a physical sub-device in the rotating body vibration integrated monitoring system 700 . The shaft vibration signal processing board 300 is a technical configuration for processing the shaft vibration of the rotating body by synchronizing the blade vibration signal processing board 200 and the phase synchronization signal.

The axial vibration signal input unit 103 has a built-in sensor interface board including a protection circuit composed of a surge varistor, a zener diode, etc., and an axial vibration signal stabilization device ( 310) and the shaft vibration signal processing module 340 are automatically set and operated.

The shaft vibration signal stabilization device 310 filters the input signal to a set band in response to the unique identifier, extracts only the desired band signal, amplifies it to a predetermined level, and electrically stabilizes it.

The axial vibration A/D converter 315 included in the axial vibration signal processing board 300 determines the sampling frequency by the unique identifier of the axial vibration signal input unit 103 , and is applied from the axial vibration signal stabilizing device 310 . The analog signal is determined by the unique identifier at the sampling frequency, converted into digital data, and transmitted to the FPGA of the axis vibration signal processing module 340 .

The shaft vibration phase synchronization signal detector 320 transmits and receives a phase synchronization logic signal through a Back Plain board, counts the number of rotations, receives rotation speed data from the counter 321 as an input, and detects the phase synchronization signal. The shaft vibration phase synchronization signal detector 320 provides information on the corresponding rotation speed to the shaft vibration signal processing module 340 .

The shaft vibration signal processing module 340 applies the analysis program reflected in the data storage module by the unique identifier of the shaft vibration signal input unit 103 to convert the discretized data from the shaft vibration A/D converter 315 into parallel data in the FPGA. Temporarily stores data by applying a large-capacity data storage module 341 to prevent loss during conversion, and receives the phase synchronization information from the phase synchronization signal detector 320 in a digital signal processor for high-speed signal processing and rotates the corresponding rotation It processes data in real time by calculating on a number basis.

The analysis results processed in real time by the axial vibration signal processing module 340 of the digital signal processor for high-speed signal processing are interfaced to the embedded core, which is easily accessible to peripheral devices, and the embedded core (Arm core) transmits the vibration from the communication module 350 to the rotating body vibration integrated calculation device 400 through the socket communication interface.

The recognition and setting function unit 330 of the embedded core (Arm Core) is responsible for the control necessary for acquiring various signals of the axial vibration signal processing board 300, and for measurement of harmonic component data of axial vibration, raw waveform data, etc. Generates and recognizes code for setting elements.

A signal processing code is given to the shaft signal stabilization device 310, the shaft vibration phase synchronization signal detector 320, the recognition and setting function unit 330, and the vibration signal processing module 340 of the shaft vibration signal processing board 300, and Set the acquisition environment. In particular, it receives NTP reference time and acquisition start signal (Start Bit) and shares NTP reference time information. Through the socket communication interface, it reports to the rotating body vibration integrated calculation device 400 that is the upper system, and provides interlocking control and monitoring with the rotating body vibration integrated calculation device 400 .

The axis vibration communication module 350 applies an embedded core (Arm Core) for communication interface and peripheral device control, and improves the communication speed and overload by using the harmonic component data and raw data of the axis vibration processed by the axis vibration signal processing module 340 It is transmitted to the rotating body vibration integrated computing device 400, which is the upper system, through the Internet port in a socket communication method.

Socket 5 for setting the shaft vibration board environment of the shaft vibration communication module 350 is a communication socket dedicated to the recognition and setting function unit 330 of the shaft vibration signal processing board 300 ) and time synchronization with the system setting contents.

In addition, the socket 6 of the shaft vibration communication module 350 for shaft vibration data communication is processed in real time by the shaft vibration signal processing module 340 and the waveform data (Time, rpm source) of the shaft vibration signal converted into parallel data in the FPGA. Data, Sync Raw Data, Async Raw Data), Vector Data (time, rpm, Gap, Direct Value, One X Amp Value, One X Phase Value, Two X Amp Value, Two X Phase Value, NX Amp Value, NX Phase Value , Bandpass value, Crest Factor value) and alarm data are communicated. By receiving the reference time transmitted from NTP (Network Time Protocol), the phase synchronization signal input unit 102, the phase synchronization signal generating board, the blade vibration signal processing board 200, and the shaft vibration signal processing board 300 are timed as the reference time When synchronization is completed, a data acquisition start signal (Start Bit) is generated from the environment setting module 410 of the rotating body vibration integrated calculation device 400 at the same time.

8 is a data flow diagram in an axial vibration signal processing board according to an embodiment of the present invention.

In one embodiment, the shaft vibration signal processing board 300 is connected to the rotating body vibration integrated calculation device 400 and is mounted on the rotating body vibration signal processing device 600 . The environment setting module 410 in the rotating body vibration integrated computing device 400 generates a reference time in NTP (S10).

And transmit the reference time through the socket communication of the rotating body vibration integrated communication module 420 (S20) and each blade vibration signal processing board 200 and the shaft vibration signal processing board 300 having an independent IP address network A reference time is received through (S30).

And when the NTP reference time is synchronized in the blade vibration signal processing board 200 and the shaft vibration signal processing board 300 (S40), the data acquisition start signal from the environment setting module 410 of the rotating body vibration integrated computing device 400 In Start Bit is generated (S50), and transmitted to each blade vibration signal processing board 200 and the shaft vibration signal processing board 300 having an IP address through the network.

Then, the phase synchronization signal input unit 102 shares the data acquisition start signal (Start Bit) through the Back Plain board, and when the NTP standard time synchronization (S40) and AND condition are satisfied, the signal from the phase synchronization sensor is received. A phase-locked logic signal is generated (S70).

In addition, when the phase synchronization signal is output through the Back Plain board (S80), the axis vibration signal processing board 300 receives the phase synchronization signal and the counter 321 counts the number of revolutions (S210).

Afterwards, when the phase synchronization signal is detected by the shaft vibration phase synchronization signal detector 320 (S220), the shaft vibration signal processing module 340 uses the phase synchronization information for each number of rotations (S230) as shown in FIG. 6 (S230) Counter measurement logic of the FPGA The processing result of (231) and the FPGA buffering of the large-capacity discretized data are phase-synchronized by the number of revolutions together with the NTP reference time, and are input from the shaft vibration signal processing module 340 .

Then, the shaft vibration signal processing module 340 performs shaft vibration alarm data processing (S240), shaft vibration waveform data calculation (S250), shaft vibration order creation and GAP calculation (S260) in the DSP, and calculates the rotational vibration integrated operation of the data. Data is transmitted to the device 400 through the network (S270).

And the reference time of the reference time transmission (S20) generated in the NTP (S10) in the rotating body vibration integrated calculation device 400 performs the reference time alignment and characteristic factor extraction (S280) for each data. After aligning the reference time for each data, the characteristic factors for monitoring are extracted and the shaft vibration monitoring of the rotating body is performed in real time (S290), and stored in the database (S300).

The rotating body vibration integrated calculation device 400 is driven by the environment setting module 410, the rotating body vibration integrated communication module 420, the real-time data collection and characteristic factor monitoring unit 430 in which the real-time monitoring program is driven, and the algorithm diagnosis program and a characteristic factor extraction and trend analysis unit 440 and a database management monitoring program 450 .

In addition, as a standard equipment for generating a reference time, it may be linked with an NTP equipment to use the standard time through GPS communication.

The environment setting module 410 performs the setting of the shaft vibration signal processing board 200 and the blade vibration signal processing board 300, and generates an acquisition start signal (Start Bit) for data acquisition at the same time.

The environment setting module 410 on which the environment setting program is mounted is the shaft vibration signal processing board 200 and the blade vibration signal processing board 300 through the socket communication of the rotating body vibration integrated communication module 420 on which the communication program is mounted. Transmits the NTP reference time, and generates a data acquisition start signal (Start Bit) when the shaft vibration signal processing board 200 and the blade vibration signal processing board 300 and the phase synchronization signal generation board satisfy the reference time synchronization conditions.

The environment setting module 410 determines the operating method of the entire rotating body vibration integrated monitoring system 700 and determines the conditions and sequence regarding the data collection method of the blade vibration signal processing board 200 .

The data communication sockets of the rotating body vibration integrated communication module 420 are operated separately. And each is transmitted by an independent protocol.

Socket 1 is a configuration for setting the environment of the blade vibration signal processing board 200 . It is a dedicated communication socket of the recognition and setting function unit 260 of the blade vibration signal processing board 200 . The rotating body vibration integrated calculation device 400 and the blade vibration signal processing board 200 are time-synchronized and communicate system settings.

Socket 2 receives the arrival time (Tip-timing) data processed by the blade vibration signal processing board 200 .

Socket 3 communicates with the blade vibration signal processing board 200 for receiving the gap peak voltage data of the processed blade.

Socket 4 communicates by receiving the raw data processed by the blade vibration signal processing board 200 and the data processed by the digital filter (multi-frequency filter).

Socket 5 (axis vibration board environment setting) is a dedicated communication socket with the recognition and setting function unit 330 of the shaft vibration signal processing board 300, and synchronizes the system settings with time synchronization with the rotating body vibration integrated computing device 400. communicate

Socket 6 is a configuration for shaft vibration data communication. Waveform data (Time, rpm raw data, Sync) of the shaft vibration signal processed in real time by the shaft vibration signal processing module 340 and converted into parallel data in FPGA Raw Data, Async Raw Data), Vector Data (time, rpm, Gap, Direct Value, One X Amp Value, One X Phase Value, Two X Amp Value, Two X Phase Value, NX Amp Value, NX Phase Value, Bandpass Value) , Crest Factor) and communication to receive alarm data.

Socket 7 is a configuration for operation data communication and communicates to receive operation data and reference time of the power generation facility in one or both directions, and at the same time, the blade vibration data, shaft vibration data and operation data of the rotating body vibration integrated monitoring system 700 are It performs communication that transmits large-capacity data to the internal network through the network.

At this time, when the operation data is transmitted, the NTP is used as a reference time and is associated with the power generation facility operation system connection module 500 .

Socket n is a spare socket provided so that communication overload or additional data can be communicated by placing an extra socket.

The rotating body vibration integrated communication module 420 manages a plurality of communication sockets and calls a communication function of signal processing data at the same time. And transmits data to the database and monitoring program (450).

The real-time data collection and characteristic factor monitoring unit 430 synchronizes the blade vibration data and the shaft vibration data acquired from the rotating body vibration integrated communication module 420, rearranges the data through multiple buffers, and collects data as needed.

The program driven by the characteristic factor extraction and trend analysis unit 440 is composed of a plurality of algorithms and is set as a defined binary code and is called by the monitoring program 450 .

The characteristic factor extraction and trend analysis unit 440 is a blade tip timing analysis algorithm, a blade tip gap analysis algorithm, a synchronous component analysis algorithm of a blade original signal, asynchronous component analysis algorithm of a blade original signal, and an axis vibration linkage correlation for characteristic factor extraction Includes relationship analysis algorithms. Then, the characteristic factors for fault detection are extracted from the database 460, learned, and applied to diagnosis.

Characteristic factor extraction and trend analysis unit 440 analyzes and determines the trend of the entire rotating body through past and present trend changes and algorithms based on the blade vibration data and shaft vibration data stored in the database 460 for trend analysis do.

9 is a flowchart illustrating a time synchronization and phase synchronization method according to an embodiment of the present invention.

In one embodiment, when the rotating body vibration signal processing device 600 is booted, the phase synchronization signal input unit 102, the phase synchronization signal generating board, the blade vibration signal processing board 200, and the shaft vibration signal processing board 300 are simultaneously booted up

The environment setting module 410 in the rotating body vibration integrated calculation device 400 generates a reference time in NTP (S600) and transmits (S610).

Then, the rotating body vibration signal processing device 600 receives the reference time transmitted from the NTP (Network Time Protocol) linked to the rotating body vibration integrated computing device 400 (S620), and the phase synchronization signal input unit 102 is the phase synchronization. When the time synchronization of the signal generation board, the blade vibration signal processing board 200 and the shaft vibration signal processing board 300 is completed with the reference time (S630), at the same time, the environment setting module of the rotating body vibration integrated calculation device 400 In step 410, a data acquisition start signal (Start Bit) is generated (S640).

Then, the phase synchronization signal input unit 102, the phase synchronization signal generating board, the blade vibration signal processing board 200, and the shaft vibration signal processing board 300 through the backplane board of the rotating body vibration signal processing device 600 ) receives a data acquisition start signal (Start Bit) as a reference signal of the collection command (S500).

And when the phase synchronization signal input unit 102 shares the data acquisition start signal (Start Bit) through the Back Plain board and the NTP standard time synchronization (S630) and AND condition are satisfied, the signal from the phase synchronization sensor is received. A phase-locked logic signal is generated (S510).

In addition, when the phase synchronization signal is output through the Back Plain board (S520), the blade vibration signal processing board 200 and the shaft vibration signal processing board 300 each count the number of rotations (S530) and the phase synchronization is detected. When it is (S540), phase synchronization is performed for each rotation speed (S550).

In the phase-synchronized condition, the blade vibration signal processing board 200 detects a phase-lock signal in the blade vibration phase-lock signal detector 250 and processes the discretized blade vibration data for each rotation speed (S560). At the same time, the shaft vibration phase synchronization signal detector 320 of the shaft vibration signal processing board 300 also detects the phase synchronization signal, processes the shaft vibration discretization data for each number of rotations (S565), and vibrates the rotating body through socket communication through the network It is transmitted to the integrated arithmetic unit 400 and processes the phase-synchronous data corresponding to the next rotation in real time.

The rotating body vibration integrated computing device 400 receives data through the network in real time (S570), sorts the received data by reference time (S580), and stores the data in real-time monitoring (S595) or a database (S590).

The power generation facility operation system connection module 500 is a module that connects operation data of the power generation facility operation system of the power plant through communication through the power plant internal network. The power generation facility operation system link module 500 synchronizes with operation data such as generator output, IGV valve opening degree, flow rate, etc. of the facility in the characteristic factor extraction and trend analysis unit 440 , real-time data collection and characteristic factor monitoring unit 430 . In association, it is visualized through the monitoring program 450 and transmitted from the database 460 .

In one embodiment, the power generation facility operation data of the power plant connected by communication through the network inside the power plant through the power generation facility operation system linkage module 500 is transmitted through the Internet port in a socket communication method or OPC communication method, When transmitting operation data, NTP is linked with the reference time of the rotating body vibration integrated calculation device 400 .

At this time, the socket 7 of the power generation facility operation system connection module 500 is for operation data communication and communicates by transmitting the operation data and reference time of the power generation facility in one direction or in both directions, and at the same time, the blade of the rotating body vibration integrated monitoring system 700 It communicates by transmitting large-capacity data of vibration data, shaft vibration data and operation data to the internal network through the network.

The above-described method may be implemented as an application or implemented in the form of program instructions that may be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination.

The program instructions recorded on the computer-readable recording medium are specially designed and configured for the present invention, and may be known and available to those skilled in the computer software field.

Examples of the computer-readable recording medium include a hard disk, a magnetic medium such as a floppy disk and a magnetic tape, an optical recording medium such as a CD-ROM, a DVD, and a magneto-optical medium such as a floppy disk. media), and hardware devices specially configured to store and execute program instructions such as ROM, RAM, flash memory, and the like.

Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules to perform processing according to the present invention, and vice versa.

Although the above has been described with reference to the embodiments, those skilled in the art will understand that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. will be able

90: sensor unit 200: blade vibration signal processing board
300: shaft vibration signal processing board 400: rotating body vibration integrated calculation device
500: power generation facility operation system linkage module
600: Rotating body vibration signal processing device 700: Rotating body vibration integrated monitoring system

Claims (33)

A blade-axis assembly rotating body vibration signal processing board, comprising:
a shaft vibration signal input unit for receiving a shaft vibration detection signal from the shaft vibration sensor system of the rotating shaft support bearing unit;
an axial oscillation phase-locked signal detector for detecting a phase-locked signal; and
A shaft vibration signal processing module that receives phase synchronization information from the phase synchronization signal detector and processes the shaft vibration detection signal of the rotating body by synchronizing the phase synchronization signal with the blade vibration signal processing board
A vibration signal processing board comprising a. The method of claim 1,
A shaft vibration signal stabilizing device that filters the shaft vibration detection signal input to the shaft vibration signal input unit to a set band, extracts only a desired band signal, amplifies it to a predetermined level, and electrically stabilizes it
A vibration signal processing board further comprising a. The method of claim 1,
A shaft vibration communication module that communicates with the integrated rotating body vibration calculation device in a socket communication method and transmits the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device
Vibration signal processing board further comprising. 4. The method of claim 3,
The axial vibration communication module,
A vibration signal processing board that applies an embedded core for controlling peripheral devices and transmits it to the rotating body vibration integrated computing device through a socket communication interface. 4. The method of claim 3,
The axial vibration communication module,
Transmitting the harmonic component data and raw data of the shaft vibration processed in the shaft vibration signal processing module to the rotating body vibration integrated computing device through the Internet port in a socket communication method that improves communication speed and overload board. The method of claim 1,
The axial vibration signal processing module is included in a digital signal processor for high-speed signal processing, the vibration signal processing board. The method of claim 1,
The shaft vibration signal processing module is a vibration signal processing board that processes and analyzes data in real time by calculating based on the number of rotations of the blade-shaft assembly rotating body. 8. The method of claim 7,
The shaft vibration phase synchronization signal detector transmits and receives a phase synchronization logic signal through a Back Plain board, counts the number of rotations to determine the rotation speed data, detects the phase synchronization signal, and transmits the information of the rotation speed. Vibration signal processing board provided as a vibration signal processing module. The method of claim 1,
The shaft vibration signal processing module measures the peak signal from the shaft vibration sensor system input to the shaft vibration signal input unit and processes the shaft vibration in the rotating shaft support bearing as a firmware-based signal. The method of claim 1,
The axial vibration signal processing module,
A vibration signal processing board that processes shaft vibration alarm data in DSP, calculates shaft vibration waveform data, calculates shaft vibration order components and GAP, and transmits data to the rotating body vibration integrated arithmetic unit through a network. The method of claim 1,
The axial vibration sensor system,
A vibration signal processing board that measures the vibration displacement with respect to the rotation shaft by installing an eddy current vibration sensor with two non-contact vibration sensors at an interval of 90° at each vibration measurement position of the rotation shaft support bearing. A method for processing a shaft vibration signal for integrated monitoring of vibration of a blade-shaft assembly rotating body, the method comprising:
Receiving a shaft vibration detection signal from the shaft vibration sensor system of the rotating shaft support bearing unit;
detecting a phase lock signal;
Synchronizing the blade vibration signal processing board and the phase synchronization signal by receiving the phase synchronization information from the phase synchronization signal detector; and
Processing the shaft vibration detection signal of the rotating body
An axial vibration signal processing method comprising a. 13. The method of claim 12,
filtering the shaft vibration detection signal input to the shaft vibration signal input unit into a set band;
Extracting only the desired band signal, amplifying it to a predetermined level, and electrically stabilizing it
Axial vibration signal processing method further comprising. 13. The method of claim 12,
Communication with the rotating body vibration integrated computing device in a socket (Socket) communication method; and
Transmitting the analysis result from the shaft vibration signal processing module to the rotating body vibration integrated calculation device
Axial vibration signal processing method further comprising. 15. The method of claim 14,
The step of communicating with the rotating body vibration integrated computing device in a socket communication method is,
Applying an embedded core for peripheral device control and transmitting it to the rotating body vibration integrated computing device through the socket communication interface
Including, axial vibration signal processing method. 15. The method of claim 14,
Transmitting the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device,
Transmitting the harmonic component data and raw data of the shaft vibration processed by the shaft vibration signal processing module to the rotating body vibration integrated computing device through the Internet port in a socket communication method that improves communication speed and overload
Including, axial vibration signal processing method. 17. The method of claim 16,
The axial vibration signal processing module is included in a digital signal processor for high-speed signal processing, the axial vibration signal processing method. 13. The method of claim 12,
Calculating based on the rotation speed of the blade-axis assembly rotating body and processing and analyzing data in real time
Axial vibration signal processing method further comprising. 19. The method of claim 18,
A shaft vibration phase synchronization signal detector, transmitting and receiving a phase synchronization logic signal through a back plane (Back Plain) board, counting the number of revolutions to determine the number of revolutions data; and
Step, by the shaft vibration phase synchronization signal detector, detecting the phase synchronization signal and providing information on the number of rotations to the shaft vibration signal processing module
Axial vibration signal processing method further comprising. 13. The method of claim 12,
The step of processing the shaft vibration detection signal of the rotating body,
measuring a peak signal from an axial vibration sensor system input to an axial vibration signal input unit; and
Step of processing the shaft vibration in the rotating shaft support bearing based on firmware
Axial vibration signal processing method further comprising. 13. The method of claim 12,
The step of processing the shaft vibration detection signal of the rotating body,
Calculating shaft vibration alarm data processing, shaft vibration waveform data calculation, shaft vibration order component and GAP in DSP; and
Transmitting data to the rotating body vibration integrated computing device through the network
Including, axial vibration signal processing method. 13. The method of claim 12,
measuring, by the shaft vibration sensor system, an eddy current vibration sensor with two non-contact vibration sensors at intervals of 90° at each vibration measurement position of the rotation shaft support bearing to measure the vibration displacement with respect to the rotation shaft
Further comprising, axial vibration signal processing method. A rotating body vibration signal monitoring system comprising a blade-shaft assembly rotating body vibration signal processing board,
The vibration signal processing board,
a shaft vibration signal input unit for receiving a shaft vibration detection signal from the shaft vibration sensor system of the rotating shaft support bearing unit;
an axial oscillation phase-locked signal detector for detecting a phase-locked signal; and
A shaft vibration signal processing module that receives phase synchronization information from the phase synchronization signal detector and processes the shaft vibration detection signal of the rotating body by synchronizing the phase synchronization signal with the blade vibration signal processing board
Including, the rotating body vibration signal monitoring system. 24. The method of claim 23,
A shaft vibration signal stabilizing device for filtering the shaft vibration detection signal input to the shaft vibration signal input unit into a set band, extracting only the desired band signal, amplifying it to a predetermined level, and electrically stabilizing the shaft vibration signal
Rotating body vibration signal monitoring system further comprising. 24. The method of claim 23,
A shaft vibration communication module that communicates with the integrated rotating body vibration calculation device in a socket communication method and transmits the analysis result in the shaft vibration signal processing module to the rotating body vibration integrated calculation device
Rotating body vibration signal monitoring system further comprising. 26. The method of claim 25,
The axial vibration communication module,
A rotating body vibration signal monitoring system that applies an embedded core (Arm Core) for controlling peripheral devices and transmits it to the rotating body vibration integrated computing device through a socket communication interface. 26. The method of claim 25,
The axial vibration communication module,
Transmitting the harmonic component data and raw data of the shaft vibration processed in the shaft vibration signal processing module to the rotating body vibration integrated computing device through the Internet port in a socket communication method that improves communication speed and overload signal monitoring system. 24. The method of claim 23,
Shaft vibration signal processing module is included in a digital signal processor for high-speed signal processing (Digital Signal Processor), the rotating body vibration signal monitoring system. 24. The method of claim 23,
The shaft vibration signal processing module, the blade-shaft assembly rotational speed based on the calculation to process and analyze the data in real time, the rotation body vibration signal monitoring system. 30. The method of claim 29,
The shaft vibration phase synchronization signal detector transmits and receives a phase synchronization logic signal through a Back Plain board, counts the number of rotations to determine the rotation speed data, detects the phase synchronization signal, and transmits the information of the rotation speed. Rotating body vibration signal monitoring system provided by the vibration signal processing module. 24. The method of claim 23,
The shaft vibration signal processing module measures the peak signal from the shaft vibration sensor system input to the shaft vibration signal input unit and processes the shaft vibration in the rotating shaft support bearing as a firmware-based signal. 24. The method of claim 23,
The axial vibration signal processing module,
A rotating body vibration signal monitoring system that processes shaft vibration alarm data in DSP, calculates shaft vibration waveform data, calculates shaft vibration order components and GAP, and transmits data to the rotating body vibration integrated computing device through a network. 24. The method of claim 23,
The axial vibration sensor system,
A rotating body vibration signal monitoring system that measures the vibration displacement with respect to the rotating shaft by installing an eddy current vibration sensor with two non-contact vibration sensors at an interval of 90° at each vibration measurement position of the rotating shaft support bearing.

Images