scholarly journals Development of a fiber optic sensor for hydrogen monitoring in transformers

2021 ◽  
Author(s):  
◽  
Maximilian Fisser
Keyword(s):  
Hydrogen Concentration ◽  
Health Monitoring ◽  
Hydrogen Sensor ◽  
Transformer Oil ◽  
Fiber Optic Sensor ◽  
Reference Structure ◽  
Strain Transfer ◽  
Rate Of Increase ◽  
Palladium Foil ◽  
Dissolved Hydrogen

<p>Electric vehicles and photovoltaic power generation are two of factors that are increasing the demands on the electrical grid. To cope with these challenges and to improve grid stability, the development of a transformer monitoring system as a fundamental part of the smart grid is necessary. Dissolved hydrogen in the transformer oil can serve as a primary indicator of the transformer health. Depending on the hydrogen concentration and rate of increase the transformer can be diagnosed.  The goal of this thesis was to develop a highly sensitive hydrogen sensor for online health monitoring of transformers.  The developed sensors are based on palladium and fiber Bragg gratings (FBG). Palladium expands with hydrogen absorption and this expansion is measured with an FBG. Detailed guidance for optimizing the sensor design is given. First, the selection of the working temperature is discussed. Second, the influence of the palladium geometry on the sensitivity is elaborated: by varying the cross-sectional area ratio of palladium to fiber the sensitivity can be tuned. Two different options to attach palladium are discussed: vapour deposition of palladium and adhesive bonding of palladium foils. The sensitivity of the palladium foil sensors was improved by improved manufacturing processes. The foil sensor have a sensitivity of up to 295 pm/% hydrogen and a resolution of 0.006% hydrogen in gas atmosphere at 90◦C and 1060 mbar.  To further increase the hydrogen sensitivity two concepts for amplification of the signal are presented. One relies on palladium silver foils, which have an increased hydrogen solubility and therefore expansion compared to pure palladium, which achieved an increase in sensitivity of a factor of 17. This leads to sensitivity of over 4500 pm/% hydrogen, which is the most sensitive hydrogen sensor reported so far. The other concept relies on a novel concept for strain concentration using a pre-strained palladium foil and FBG, which achieved an amplification of a factor of 2.5.  The sensors were characterised in gas and oil environment in a newly developed setup which is stable in pressure, temperature and gas concentration. In gas the sensors were tested at 60, 75, 90, 105, and 120◦C and for a hydrogen concentration range of 0.01 (100 ppm) to 5%. In oil the sensor was tested at 90◦C and for a hydrogen concentration range of 5- 4000 ppm dissolved hydrogen. Furthermore, the influence of carbon monoxide (CO) on the hydrogen sensitivity was examined. A slowed response could be observed, but CO had no impact on the precision of the sensor.  Finally, the hydrogen calibration of the sensor is discussed by investigating the strain transfer between expanding palladium and fiber. Three different methods are elaborated to determine the coefficient of strain transfer: (a) via hydrogen measurement, (b) via temperature measurement, and (c) via strain measurement. Methods (a) and (b) were applied directly on the hydrogen sensor, and gave similar results. Method (c) was applied on a reference structure and used to verify method (b).  A hydrogen sensor suitable for transformer health monitoring has been developed and characterised, and is currently being implemented in a transformer in the New Zealand network.</p>

scholarly journals Development of a fiber optic sensor for hydrogen monitoring in transformers

2021 ◽  
Author(s):  
◽  
Maximilian Fisser
Keyword(s):  
Hydrogen Concentration ◽  
Health Monitoring ◽  
Hydrogen Sensor ◽  
Transformer Oil ◽  
Fiber Optic Sensor ◽  
Reference Structure ◽  
Strain Transfer ◽  
Rate Of Increase ◽  
Palladium Foil ◽  
Dissolved Hydrogen

<p>Electric vehicles and photovoltaic power generation are two of factors that are increasing the demands on the electrical grid. To cope with these challenges and to improve grid stability, the development of a transformer monitoring system as a fundamental part of the smart grid is necessary. Dissolved hydrogen in the transformer oil can serve as a primary indicator of the transformer health. Depending on the hydrogen concentration and rate of increase the transformer can be diagnosed.  The goal of this thesis was to develop a highly sensitive hydrogen sensor for online health monitoring of transformers.  The developed sensors are based on palladium and fiber Bragg gratings (FBG). Palladium expands with hydrogen absorption and this expansion is measured with an FBG. Detailed guidance for optimizing the sensor design is given. First, the selection of the working temperature is discussed. Second, the influence of the palladium geometry on the sensitivity is elaborated: by varying the cross-sectional area ratio of palladium to fiber the sensitivity can be tuned. Two different options to attach palladium are discussed: vapour deposition of palladium and adhesive bonding of palladium foils. The sensitivity of the palladium foil sensors was improved by improved manufacturing processes. The foil sensor have a sensitivity of up to 295 pm/% hydrogen and a resolution of 0.006% hydrogen in gas atmosphere at 90◦C and 1060 mbar.  To further increase the hydrogen sensitivity two concepts for amplification of the signal are presented. One relies on palladium silver foils, which have an increased hydrogen solubility and therefore expansion compared to pure palladium, which achieved an increase in sensitivity of a factor of 17. This leads to sensitivity of over 4500 pm/% hydrogen, which is the most sensitive hydrogen sensor reported so far. The other concept relies on a novel concept for strain concentration using a pre-strained palladium foil and FBG, which achieved an amplification of a factor of 2.5.  The sensors were characterised in gas and oil environment in a newly developed setup which is stable in pressure, temperature and gas concentration. In gas the sensors were tested at 60, 75, 90, 105, and 120◦C and for a hydrogen concentration range of 0.01 (100 ppm) to 5%. In oil the sensor was tested at 90◦C and for a hydrogen concentration range of 5- 4000 ppm dissolved hydrogen. Furthermore, the influence of carbon monoxide (CO) on the hydrogen sensitivity was examined. A slowed response could be observed, but CO had no impact on the precision of the sensor.  Finally, the hydrogen calibration of the sensor is discussed by investigating the strain transfer between expanding palladium and fiber. Three different methods are elaborated to determine the coefficient of strain transfer: (a) via hydrogen measurement, (b) via temperature measurement, and (c) via strain measurement. Methods (a) and (b) were applied directly on the hydrogen sensor, and gave similar results. Method (c) was applied on a reference structure and used to verify method (b).  A hydrogen sensor suitable for transformer health monitoring has been developed and characterised, and is currently being implemented in a transformer in the New Zealand network.</p>

scholarly journals Response Time of a Fiber Bragg Grating Based Hydrogen Sensor for Transformer Monitoring

Proceedings ◽  
2018 ◽  
Vol 2 (13) ◽  
pp. 745
Author(s):  
Arvid Hunze ◽  
Rodney A. Badcock ◽  
Maximilian Fisser
Keyword(s):  
Response Time ◽  
Hydrogen Diffusion ◽  
Hydrogen Sensor ◽  
Hydrogen Uptake ◽  
Transformer Oil ◽  
Fiber Optic Sensor ◽  
Nitrogen Gas ◽  
Palladium Surface ◽  
Hydrogen Response ◽  
Different Response

We developed and optimized a new fiber optic sensor using palladium foils attached to optical fiber Bragg gratings (FBG) for hydrogen measurements. Fifteen in parallel processed sensors were characterized and qualified in two custom tailored experimental set ups and their response to a 5% hydrogen/nitrogen gas mixture and the same gas bubbled trough transformer oil was measured. The hydrogen response is similar for both medium and close to the theoretical maximum sensitivity, but the response time was found to be very different, much slower in oil than in gas. A theoretical comparison of hydrogen diffusion trough palladium and hydrogen absorption on the palladium surface as well as a measurement of the hydrogen uptake and diffusion trough the oil to the sensor have been done to investigate the origin of the different response time. They indicate that the response time determining step is the absorption of hydrogen on the palladium surface and that this process is slowed down in oil compared to a pure gas environment.

scholarly journals Case Study of Anaerobic Digestion Process Stability Detected by Dissolved Hydrogen Concentration

Processes ◽  
2021 ◽  
Vol 9 (1) ◽  
pp. 106
Author(s):  
Daniela Platošová ◽  
Jiří Rusín ◽  
Jan Platoš ◽  
Kateřina Smutná ◽  
Roman Buryjan
Keyword(s):  
Anaerobic Digestion ◽  
Correlation Coefficient ◽  
Hydrogen Concentration ◽  
Pearson’S Correlation ◽  
Pearson’S Correlation Coefficient ◽  
Digestion Process ◽  
Short Service Life ◽  
Pearson's Correlation ◽  
Dissolved Hydrogen ◽  
Pearson's Correlation Coefficient

The paper presents the results of a laboratory experiment of mesophilic single-stage anaerobic digestion performed to verify the possibility of early detection of process instability and reactor overload by evaluating the course of dissolved hydrogen concentration of the main intermediate. The digestion process was run in a Terrafors IS rotary drum bioreactor for 230 days. The substrate dosed on weekdays was food leftovers from the university canteen. At an average temperature of 37 °C, an organic loading of volatiles of 0.858 kg m−3 day−1 and a theoretical retention time of 259 days, biogas production of 0.617 Nm3 kg VS−1 was achieved with a CH4 content of 51.7 vol. %. The values of the established FOS/TAC stability indicator ranged from 0.26 to 11.4. The highest value was reached when the reactor was overloaded. The dissolved hydrogen concentration measured by the amperometric microsensor ranged from 0.039–0.425 mg dm−3. Data were statistically processed using Pearson’s correlation coefficient. The correlation of the hydrogen concentration with other parameters such as the concentration of organic acids was evaluated. The value of Pearson’s correlation coefficient was 0.331 and corresponded to a p-value of 0. The results confirmed a very low limit of the hydrogen concentration at which the microbial culture, especially methanogens, was already overloaded. The amperometric microsensor proved to be rather unsuitable for operational applications due to insufficient sensitivity and short service life. The newly designed ratio of dissolved hydrogen concentration to neutralizing capacity was tested but did not work significantly better than the established FOS/TAC stability indicator.

scholarly journals Analysis of the strain transfer in a new FBG sensor for Structural Health Monitoring

2011 ◽  
Vol 33 (2) ◽  
pp. 539-548 ◽  
Author(s):  
Benjamin Torres ◽  
Ignacio Payá-Zaforteza ◽  
Pedro A. Calderón ◽  
Jose M. Adam
Keyword(s):  
Structural Health Monitoring ◽  
Health Monitoring ◽  
Strain Transfer ◽  
Structural Health ◽  
Fbg Sensor

scholarly journals High Strain Survivability of Piezoceramics by Optimal Bonding Adhesive Design

Sensors ◽  
2018 ◽  
Vol 18 (8) ◽  
pp. 2554 ◽  
Author(s):  
Hu Sun ◽  
Yishou Wang ◽  
Xinlin Qing ◽  
Zhanjun Wu
Keyword(s):  
Finite Element Analysis ◽  
Health Monitoring ◽  
Tensile Strain ◽  
High Strain ◽  
Aerospace Industry ◽  
Element Analysis ◽  
Strain Transfer ◽  
Impact Monitoring ◽  
Novel Approach ◽  
Host Structure

As one of the most common transducers used in structural health monitoring (SHM), piezoceramic sensors can play an important role in both damage detection and impact monitoring. However, the low tensile strain survivability of piezoceramics resulting from the material nature significantly limits their application on SHM in the aerospace industry. This paper proposes a novel approach to greatly improve the strain survivability of piezoceramics by optimal design of the adhesive used to bond them to the host structure. Theoretical model for determining the strain transfer coefficient through bonded adhesive from the host structure to piezoceramic is first established. Finite element analysis is then utilized to study the parameters of adhesive, including thickness and shear modulus. Experiments are finally conducted to validate the proposed method, and results show the piezoceramic sensors still work well when they are bonded on the host structures with tensile strain up to 4000 με by using the optimal adhesive.

Study and Application of Health Monitoring by Fiber Optic Sensors in Civil Engineering

2003 ◽  
Author(s):  
Hong-Nan Li ◽  
Dong-Sheng Li ◽  
Su-Yan Wang
Keyword(s):  
Health Monitoring ◽  
Fiber Optic ◽  
Civil Engineering ◽  
Fiber Optic Sensor ◽  
Current Status ◽  
Fibre Optic ◽  
Engineering Structures ◽  
Monitoring Method ◽  
Structural Health ◽  
Potential Damage

In civil engineering, the smart health monitoring method by use of fiber optic sensor is a new approach that evaluates the structural health situation. The current status in applications of fibre optic structural health monitoring in civil engineering structures with a brief introduction of the advantages, basic principles of fibre optic sensors is described in this paper. Leakage detection and potential damage to pipelines are emphasized. Finally, existing problems for packing and implementing fibre optic sensors in structures are discussed.

An In-depth Review: Structural Health Monitoring using Fiber Optic Sensor

2012 ◽  
Vol 29 (2) ◽  
pp. 105 ◽  
Author(s):  
MuhammadHassan Bin Afzal ◽  
Shahid Kabir ◽  
Othman Sidek
Keyword(s):  
Structural Health Monitoring ◽  
Health Monitoring ◽  
Fiber Optic ◽  
Fiber Optic Sensor ◽  
Structural Health ◽  
Optic Sensor
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