WO2018072698A1 - Nuclear magnetic resonance measurement system for detecting degree of aging of composite insulator umbrella skirt - Google Patents

Abstract

A nuclear magnetic resonance (NMR) measurement system for detecting degree of aging of a composite insulator umbrella skirt comprises an NMR sensor, a diplexer, an NMR spectrometer, a controller, an input device, an output device and a power supply. The controller is configured to, when a control command received is an activation instruction, control the NMR spectrometer to generate a radio-frequency (RF) excitation signal. The NMR sensor is configured to, after receiving the RF excitation signal, establish a static magnetic field and an RF excitation magnetic field, and to detect an NMR echo signal. The diplexer is configured to perform switching between RF excitation signal transmission and NMR signal transmission. The NMR spectrometer is configured to perform an index inversion process on the NMR echo signal to acquire a lateral relaxation time, and to acquire the degree of aging of the composite insulator umbrella skirt according to the lateral relaxation time.

Description

Nuclear magnetic resonance measurement system for detecting the age of composite insulators Technical field

The present disclosure relates to the field of composite insulator aging detection technology, for example, to a nuclear magnetic resonance measurement system for composite insulator aging detection.

Background technique

Composite insulators should be widely installed in high-voltage transmission lines due to their light weight, high mechanical strength, non-breakability and good stain resistance. The composite insulator shed is the outer insulation of the composite insulator to protect the mandrel from atmospheric attack, provide the necessary creepage distance, and improve stain resistance. During the operation of the hanging net, the composite insulator shed may age or be broken under the erosion of the grid overvoltage and the natural environment. The aging or broken composite insulator shed reduces the safety of the power supply, so the composite insulator umbrella The detection of the degree of aging of the skirt is of great significance.

In the related art, the method for detecting the aging of the composite insulator umbrella skirt includes an observation method, a water spray classification method, a leakage current method, a contact angle method, and a thermal stimulation current method. Among them, the observation method and the HC water jet classification method are susceptible to the subjective judgment of the maintenance personnel, and the reliability is poor. The factors affecting the current magnitude in the leakage current method are complex, random, and the detection results are not reliable. The contact angle method and the thermal stimulation current method have high requirements for the test environment, and can be set to off-line measurement under laboratory conditions, and the operation is complicated.

With the continuous improvement of voltage levels in China and the interconnection between large power grids, power systems have put forward higher requirements for power supply reliability. There is an urgent need for a method for detecting the ageing degree of composite insulator umbrella skirts.

Summary of the invention

The present disclosure proposes a nuclear magnetic resonance measurement system configured to detect the degree of aging of a composite insulator, which can accurately detect the aging degree of the composite insulator shed.

A nuclear magnetic resonance detection system includes: a nuclear magnetic resonance NMR sensor, a duplexer, an NMR spectrometer, a controller, an input device, an output device, and a power source, wherein

The input device is configured to receive a control command input by a user and send the control command to The controller;

The controller is configured to control the NMR spectrometer to generate a radio frequency excitation signal when the received control command is a start command, and send the radio frequency excitation signal to the NMR sensor through the duplexer, and The nuclear magnetic resonance echo signal detected by the NMR sensor is sent to the NMR spectrometer through the duplexer;

The NMR sensor is configured to establish a static magnetic field and a radio frequency excitation magnetic field in the measured area after receiving the radio frequency excitation signal, and detect the nuclear magnetic resonance echo signal;

The duplexer is configured to perform switching between RF excitation signal transmission and nuclear magnetic resonance echo signal transmission;

The NMR spectrometer is configured to perform an exponential inversion process on the nuclear magnetic resonance echo signal to obtain a transverse relaxation time, and obtain an aging degree of the composite insulator shed according to the transverse relaxation time;

The output device is configured to output aging degree data of the composite insulator shed;

The power source is configured to power the controller and the NMR spectrometer.

Optionally, the system further includes: a power amplifier connected between the NMR spectrometer and the duplexer, wherein the power amplifier performs power amplification on the RF excitation signal sent by the NMR spectrometer And transmitting, by the duplexer, a power amplified RF excitation signal to the NMR sensor.

Optionally, the system further includes: a preamplifier connected between the NMR spectrometer and the duplexer, wherein the preamplifier amplifies the nuclear magnetic resonance echo signal, and then sends the amplified nuclear magnetic field The resonant echo signal is sent to the NMR spectrometer.

Optionally, the system further includes: a universal serial bus USB data transmission device connected to the controller, wherein the USB data transmission device is configured to connect to the mobile storage device.

Optionally, the controller is a 32-bit microcontroller based on the ARM core of the advanced reduced instruction set computer processor.

Optionally, the input device and the output device are respectively touch screens.

Optionally, the NMR spectrometer comprises: a lock-in amplifier, and the lock-in amplifier uses a phase sensitive detection method to detect a nuclear magnetic resonance echo signal.

Optionally, the power source is a lithium battery.

DRAWINGS

1 is a schematic structural view of a first nuclear magnetic resonance detecting system provided for detecting the aging degree of a composite insulator umbrella skirt according to the first embodiment;

2 is a schematic structural view of a nuclear magnetic resonance detecting system for detecting the aging degree of a composite insulator umbrella skirt according to an embodiment;

FIG. 3 is a schematic structural diagram of a third nuclear magnetic resonance detecting system configured to detect the age of a composite insulator umbrella skirt according to an embodiment;

FIG. 4 is a schematic structural diagram of a fourth nuclear magnetic resonance detection system configured to detect the age of a composite insulator umbrella skirt according to an embodiment.

detailed description

In one embodiment, from the perspective of materials science, nuclear magnetic resonance technology is used to realize the aging degree detection of the composite insulator umbrella skirt. As a non-destructive testing method, nuclear magnetic resonance technology is widely used in life medical, food analysis, quality control, materials science and geophysics. The NMR technique utilizes the magnetic resonance properties of the H nucleus to obtain the Magnetic Resonance Spectroscopy (MRS) of the H nucleus, and to understand the nature and location of the nucleus according to the characteristics of the MRS, such as the width, shape and area of the line. The environment to determine the molecular structure.

An embodiment provides a nuclear magnetic resonance detecting system for detecting the age of a composite insulator umbrella skirt, and FIG. 1 is a schematic structural view of the system, the device comprising: a nuclear magnetic resonance (NMR) sensor 11 and a double The workpiece 12, the NMR spectrometer 13, the controller 14, an input device (also referred to as an input device) 15, an output device (also referred to as an output device) 16, and a power source 17.

The input device 15 is arranged to receive a control command input by the user and to transmit the control command to the controller 14.

The controller 14 is configured to control the NMR spectrometer 13 to generate a radio frequency excitation signal when the received control command is a start command, and send the radio frequency excitation signal to the NMR sensor 11 through the duplexer 12, and detect the NMR sensor 11 The resulting nuclear magnetic resonance echo signal is sent to the NMR spectrometer 13 through the duplexer 12.

The NMR sensor 11 is arranged to establish a static magnetic field and a radio frequency excitation magnetic field in the measured region after receiving the radio frequency excitation signal, and detect the nuclear magnetic resonance echo signal.

The duplexer 12 is arranged to switch between RF excitation signal transmission and nuclear magnetic resonance echo signal transmission.

The NMR spectrometer 13 is arranged to perform an exponential inversion process on the nuclear magnetic resonance echo signal to obtain a transverse relaxation time, and the degree of aging of the composite insulator shed is obtained according to the transverse relaxation time.

The output device 16 is arranged to output the degree of aging of the composite insulator shed.

A power source 17 is provided to power the controller 14 and the NMR spectrometer 13.

The state of the hydrogen nucleus in the numerator of the composite insulator is fixed, and the transverse relaxation time T2 is fixed. When the composite insulator umbrella skirt is aged, the molecular chain of the composite insulator umbrella skirt undergoes chemical changes such as breakage and recombination, and the state of the hydrogen atomic nucleus changes. The measured transverse relaxation time T2 may also change. In this embodiment, the aging degree of the composite insulator shed is obtained by measuring the transverse relaxation time T2.

The nuclear magnetic resonance detection system for detecting the aging degree of the composite insulator umbrella skirt provided by the above embodiment uses the nuclear magnetic resonance technology to quantitatively analyze the aging degree of the composite insulator shed and improve the accuracy of the detection result. The NMR sensor detects the running composite insulator shed, which enables on-line inspection (engineering on-site inspection), improves the efficiency of the aging inspection of composite insulator sheds, and improves the reliability of power supply.

An embodiment provides a nuclear magnetic resonance detection system for detecting the age of a composite insulator umbrella skirt, and FIG. 2 shows a schematic structural view of the system. Based on the above embodiment, the system further includes a connection to the NMR spectrometer 13 And a power amplifier 18 between the duplexer 12. The power amplifier 18 power-amplifies the RF excitation signal sent by the NMR spectrometer 13 and then transmits the power-amplified RF excitation signal to the NMR sensor 11 through the duplexer 12, so that the RF energy can excite the sample to generate a nuclear magnetic resonance echo signal.

An embodiment provides a nuclear magnetic resonance detection system configured to detect the age of a composite insulator umbrella skirt, and FIG. 3 shows a schematic structural view of the system. On the basis of FIG. 2, the system further includes a connection to the NMR spectrometer 13 and A preamplifier 19 between the duplexers 12. After the preamplifier 19 amplifies the nuclear magnetic resonance echo signal, the amplified nuclear magnetic resonance echo signal is sent to the NMR spectrometer 13 to facilitate the NMR spectrometer. 13 Detecting nuclear magnetic resonance echo signals.

An embodiment provides a nuclear magnetic resonance detecting system for detecting the age of a composite insulator umbrella skirt, and FIG. 4 is a schematic structural view of the system. On the basis of FIG. 3, the system further includes a universal string connected to the controller 14. A Universal Serial Bus (USB) data transmission module (also referred to as a USB data transmission device) 20. The USB) data transfer module 20 is arranged to connect to a mobile storage device. The detection result can be copied to the mobile storage device through the USB data transmission module 20.

Optionally, the controller 14 is a 32-bit microcontroller based on a Advanced Reduced Instruction Set Computer (RISC) processor (ARM) core. Due to the high integration of the 32-bit single-chip based on the ARM core, the signal processing speed is fast, and many peripheral circuits are integrated, which reduces the volume of the above system and makes the system easy to carry.

Optionally, the input device 15 and the output device 16 are touch screens. Use the touch screen to provide human interaction. A series of operations can be performed by clicking on the touch screen, and the processed data and graphics are displayed on the display screen, which is easy to understand.

Optionally, the NMR spectrometer 13 includes a lock-in amplifier, and the lock-in amplifier uses a phase sensitive detection method to detect the nuclear magnetic resonance echo signal. The lock-in amplifier uses the phase sensitive detection method to detect the nuclear magnetic resonance echo signal, which improves the performance of the above system to suppress noise suppression. The lock-in amplifier adopts the principle of synchronous coherent detection, that is, the reference signal having the same frequency and phase relationship with the measured signal is used as a comparison reference, and only the measured signal itself and the same frequency (or frequency doubling) and in-phase noise component as the reference signal are used. There is a response. Therefore, the lock-in amplifier can suppress unwanted noise and improve the detection signal-to-noise ratio.

Optionally, the power source 17 is a lithium battery. The lithium battery has high energy density and light weight, which reduces the size and weight of the system, making the system easy to carry.

Industrial applicability

The nuclear magnetic resonance measurement system for detecting the aging degree of the composite insulator can accurately detect the aging degree of the composite insulator shed.

Claims (8)

A nuclear magnetic resonance detecting system for detecting the ageing degree of a composite insulator umbrella skirt, comprising: a nuclear magnetic resonance NMR sensor, a duplexer, an NMR spectrometer, a controller, an input device, an output device, and a power source, wherein The input device is configured to receive a control command input by a user, and send the control command to the controller; The controller is configured to control the NMR spectrometer to generate a radio frequency excitation signal when the received control command is a start command, and send the radio frequency excitation signal to the NMR sensor through the duplexer, and The nuclear magnetic resonance echo signal detected by the NMR sensor is sent to the NMR spectrometer through the duplexer; The NMR sensor is configured to establish a static magnetic field and a radio frequency excitation magnetic field in the measured area after receiving the radio frequency excitation signal, and detect the nuclear magnetic resonance echo signal; The duplexer is configured to perform switching between RF excitation signal transmission and nuclear magnetic resonance echo signal transmission; The NMR spectrometer is configured to perform an exponential inversion process on the nuclear magnetic resonance echo signal to obtain a transverse relaxation time, and obtain an aging degree of the composite insulator shed according to the transverse relaxation time; The output device is configured to output aging degree data of the composite insulator shed; The power source is configured to power the controller and the NMR spectrometer. The system of claim 1 further comprising: a power amplifier coupled between said NMR spectrometer and said duplexer, wherein said power amplifier powers said RF excitation signal transmitted by said NMR spectrometer After amplification, a power amplified RF excitation signal is transmitted through the duplexer to the NMR sensor. The system of claim 1 further comprising: said NMR spectrometer and said pair A preamplifier between the devices, wherein the preamplifier amplifies the nuclear magnetic resonance echo signal and then transmits the amplified nuclear magnetic resonance echo signal to the NMR spectrometer. The system of claim 1 further comprising: a universal serial bus USB data transfer device coupled to said controller, wherein said USB data transfer device is configured to connect to the mobile storage device. The system of claim 1 wherein said controller is a 32-bit microcontroller based on an advanced reduced instruction set computer processor ARM core. The system of claim 1 wherein said input device and said output device are each a touch screen. The system of claim 1 wherein said NMR spectrometer comprises: a lock-in amplifier, and said lock-in amplifier uses a phase sensitive detection method to detect a nuclear magnetic resonance echo signal. The system of claim 1 wherein said power source is a lithium battery.

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