Downhole fiber optic sensing: the oilfield service provider's perspective: from the cradle to the grave

Skinner, Neal G.; Maida, John L.

doi:10.1117/12.2049846

Cited by 6 publications

(3 citation statements)

References 38 publications

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“…Sun et al (2021) discussed three typical DFOS deployed ground military system projects and explored two research results to guide the on-site application of ground military systems for wide use in future large-scale all optical ground military system monitoring stations. The application of distributed fibre optic sensing technology has been greatly expanded in the oil and gas industry (Baldwin, 2015; Skinner and Maida, 2014), especially in the field of well monitoring (Sasaki et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Research on the deformation and settlement characteristics of tunnel lining structures based on distributed fibre optic sensing technology

Wu,

Sheng,

Zhang

et al. 2024

Advances in Structural Engineering

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To study the deformation and settlement characteristics of tunnel lining structures, a tunnel lining structure model was designed based on distributed fibre optic sensing technology. Compared to the cylindrical model used in traditional tunnel lining structural model experiments, in this study, a reinforced concrete structural model was adopted, which can embed fibre optics in the structure, which is closer to actual tunnel engineering conditions. Central and symmetrical concentrated loading experiments were carried out with a simply supported reaction frame. The results of the distributed fibre optic monitoring were compared and analysed with those of traditional monitoring methods to verify the reliability of the distributed fibre optic monitoring results. The numerical simulations of the experiments were conducted by using finite element analysis. By comparing and analysing the simulation and experimental results, the correctness of the simulation calculation results were verified. On this basis, the impact of concrete strength, circumferential reinforcement spacing, and longitudinal reinforcement strength on the deformation and settlement of the tunnel lining structure were analysed. The results show that the hierarchical effect of the strain monitoring results obtained by the embedded fibre optic is more obvious, indicating that the radial monitoring effect of the embedded fibre optic on the tunnel structure is less affected by other external factors than the strain gauge, and the monitoring data are more accurate and effective, with good engineering characteristics. Improving the concrete strength, appropriate circumferential reinforcement spacing, and increasing the longitudinal reinforcement strength can effectively enhance the ability of the structure to resist deformation at the stress location. These factors play a significant role in improving the overall resistance to deformation and safety of the structure. The research results provide a theoretical basis and experimental data for the application of distributed fibre optics in monitoring the deformation and settlement of tunnel lining structures.

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Section: Introductionmentioning

confidence: 99%

Research on the deformation and settlement characteristics of tunnel lining structures based on distributed fibre optic sensing technology

Wu,

Sheng,

Zhang

et al. 2024

Advances in Structural Engineering

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“…Due to complex and changeable downhole conditions, most scholars concentrate on the theoretical level of downhole vibration [3] such as mathematical models [4,5], which cannot provide feedback to the actual downhole state. For the measurement method of downhole vibration, most scholars install sensors at the bottom of the hole to measure downhole vibration, such as acceleration sensors [6,7], acoustic sensors [8], optical sensing technology [9], and so on. Furthermore, some researchers monitor vibration by affixing sensors to the hole's surface [10,11].…”

Section: Introductionmentioning

confidence: 99%

Experiment Study of Deformable Honeycomb Triboelectric Nanogenerator for Energy Collection and Vibration Measurement in Downhole

Feng,

Pan,

2024

Applied Sciences

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Downhole drilling tool vibration measurement is crucial for drilling exploration safety, so real-time monitoring of vibration data is required. In this research, a honeycomb triboelectric nanogenerator (H-TENG) capable of adapting to various downhole environments is proposed. It can measure the frequency of downhole drilling equipment’s vibrations and transfer mechanical energy to electrical energy for use in powering other low power downhole meters. In order to preliminarily verify the possibility of sensors used for vibration measurement of downhole drilling tools, we built a simulated vibration platform to test the sensing performance and vibration energy collection performance of H-TENG. According to the testing results, the measurement range of vibration frequency and amplitude are 0 to 11 Hz and 5 to 25 mm, respectively, and the corresponding measurement errors are less than 5% and 6%, respectively. For vibrational energy harvesting, when four sensors are wired in series with a 107 resistance, the maximum power is approximately 1.57 μW. Compared to typical methods for measuring downhole vibration, the honeycomb triboelectric nanogenerator does not need an external power source, it has greater reliability and output power, and it can vary its shape to adapt to the complicated downhole environment. In addition, the H-TENG can be combined freely according to the diameter of the drill string, and even if one sensor unit is damaged, the other units can still be used normally.

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“…Measurements of high temperatures are of great significance in a variety of industrial applications, such as aerospace [1] and petrochemical engineering [2]. Over the past few decades, various fiber-optic sensors have been developed for high-temperature measurements, such as ultrafast laser-induced fiber Bragg gratings (FBGs) [3,4], sapphire FBG [5], long-period fiber gratings inscribed into a non-photosensitive fiber by a CO 2 laser [6] or arc discharge [7], fiber Mach-Zehnder interferometers (MZIs) [8,9] and fiber Fabry-Perot interferometers (FPIs) [10,11].…”

Section: Introductionmentioning

confidence: 99%

Hollow-Core Fiber-Tip Interferometric High-Temperature Sensor Operating at 1100 °C with High Linearity

Zhang

Zhou

et al. 2021

Micromachines

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Over decades, fiber-optic temperature sensors based on conventional single-mode fibers (SMF) have been demonstrated with either high linearity and stability in a limited temperature region or poor linearity and thermal hysteresis in a high-temperature measurement range. For high-temperature measurements, isothermal annealing is typically necessary for the fiber-optic sensors, aiming at releasing the residual stress, eliminating the thermal hysteresis and, thus, improving the high-temperature measurement linearity and stability. In this article, an annealing-free fiber-optic high-temperature (1100 °C) sensor based on a diaphragm-free hollow-core fiber (HCF) Fabry-Perot interferometer (FPI) is proposed and experimentally demonstrated. The proposed sensor exhibits an excellent thermal stability and linearity (R2 > 0.99 in a 100–1100 °C range) without the need for high-temperature annealing. The proposed sensor is extremely simple in preparation, and the annealing-free property can reduce the cost of sensor production significantly, which is promising in mass production and industry applications.

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Downhole fiber optic sensing: the oilfield service provider's perspective: from the cradle to the grave

Cited by 6 publications

References 38 publications

Research on the deformation and settlement characteristics of tunnel lining structures based on distributed fibre optic sensing technology

Research on the deformation and settlement characteristics of tunnel lining structures based on distributed fibre optic sensing technology

Experiment Study of Deformable Honeycomb Triboelectric Nanogenerator for Energy Collection and Vibration Measurement in Downhole

Hollow-Core Fiber-Tip Interferometric High-Temperature Sensor Operating at 1100 °C with High Linearity

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