Your search keyword '"Yuan, Jinsha"' showing total 3 results

1. Effects of Nanoparticle Materials on Prebreakdown and Breakdown Properties of Transformer Oil.

Author

Lv, Yuzhen, Ge, Yang, Wang, Lei, Sun, Zhen, Zhou, You, Huang, Meng, Li, Chengrong, Yuan, Jinsha, and Qi, Bo

Subjects

INSULATING oils, NANOPARTICLES, NANOFLUIDS

Abstract

Featured Application: This work is of practical value in predicting the breakdown accidents and of theoretical importance in reducing the volume of power equipment. In order to reveal the effects of nanoparticle materials on prebreakdown and breakdown properties of transformer oil, three types of nanoparticle materials, including conductive Fe3O4, semiconductive TiO2 and insulating Al2O3 nanoparticles, were prepared with the same size and surface modification. An experimental study on the breakdown strength and prebreakdown streamer propagation characteristics were investigated for transformer oil and three types of nanofluids under positive lightning impulse voltage. The results indicate that the type of nanoparticle materials has a notable impact on breakdown strength and streamer propagation characteristics of transformer oil. Breakdown voltages of nanofluids are markedly increased by 41.3% and 29.8% respectively by the presence of Fe3O4 and TiO2 nanoparticles. Whereas a slight increase of only 7.4% is observed for Al2O3 nanofluid. Moreover, main discharge channels with thicker and denser branches are formed and the streamer propagation velocities are greatly lowered both in Fe3O4 and TiO2 nanofluids, while no obvious change appears in the propagation process of streamers in Al2O3 nanofluid in comparison with that in pure oil. The test results of trap characteristics reveal that the densities of shallow traps both in Fe3O4 and TiO2 nanofluids are much higher than that in Al2O3 nanofluid and pure oil, greatly reducing the distortion of the electric field. Thus, the propagations of positive streamers in the nanofluids are significantly suppressed by Fe3O4 and TiO2 nanoparticles, leading to the improvements of breakdown strength. [ABSTRACT FROM AUTHOR]

Published

2018

2. Fractal Analysis of Positive Streamer Patterns in Transformer Oil-Based TiO2 Nanofluid.

Author

Lv, Yuzhen, Ge, Yang, Du, Qian, Sun, Qian, Shan, Bingliang, Huang, Meng, Li, Chengrong, Qi, Bo, and Yuan, Jinsha

Subjects

NANOFLUIDS, TITANIUM dioxide, FRACTAL analysis, INSULATING oils, SCHLIEREN methods (Optics)

Abstract

In this paper, prebreakdown streamers in transformer oil and transformer oil-based TiO2 nanofluid were observed by the schlieren method under positive lightning impulse voltage. Streamers in the nanofluid have numerous branches with much shorter length, whereas in the pure oil, they exhibit only certain filaments with longer length. The discrepancy in positive streamer pattern of both oils is further investigated under a range of applied voltages. The complexity of streamer patterns was quantitatively described using the fractal analysis method. Results indicate that the fractal dimension of streamer patterns shows different changing tendencies in both oils, and it keeps higher value in the nanofluid than that in pure oil during the whole propagation process, well corresponding with streamer propagating structures. Moreover, a new parameter, the ratio of fractal dimension to propagation length (D/L), is introduced to classify the complex streamer patterns for the first time. Three propagation zones in both nanofluid and pure oil are clearly categorized by the value of D/L, providing a quantitative way to distinguish the streamer patterns. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Effect of TiO2 nanoparticles on streamer propagation in transformer oil under lightning impulse voltage.

Author

Lv, Yuzhen, Ge, Yang, Li, Chengrong, Wang, Qi, Zhou, You, Qi, Bo, Yi, Kai, Chen, Xin, and Yuan, Jinsha

Subjects

TITANIUM dioxide nanoparticles, INSULATING oils, ELECTRIC discharge lighting, ELECTRIC potential, ELECTRIC breakdown

Abstract

Recent experiments have shown that some nanoparticles can influence the breakdown strength of transformer oil under lightning impulse voltage. To reveal the working mechanism, this paper presents an experimental study on the effect of TiO2 nanoparticles on the impulse breakdown strength and prebreakdown streamer propagation process in transformer oil-based nanofluid under both positive and negative lightning impulse voltage. The test results verify that the modification of nanoparticles on breakdown strength of transformer oil has a distinct polar effect: positive breakdown voltage of nanofluid is increased by up to 30.8%, whereas the negative one is decreased by 6.8%. Streamer shape, propagation length and velocity in both pure oil and nanofluid were investigated using the shadowgraph technique. It is revealed that the propagation characteristics of positive and negative streamers in nanofluid are markedly affected by the addition of TiO2 nanoparticles. The positive streamers in nanofluid form a bush-like structure with thicker and denser branches, developing much slower than tree-like streamers in pure oil. While negative streamers in nanofluid have a tree-like shape with much longer branches, propagating faster than the original bush-like streamer in pure oil. These differences in streamer propagation characteristics and breakdown strength in pure oil and nanofluid are closely related to the change of space charge distribution caused by shallow trap in nanofluid. More negative charges are formed through capturing fast electrons into slow electrons in shallow traps induced by the presence of TiO2 nanoparticles, which change the local electric field in front of the streamer tip. Thus, streamer propagation process in nanofluid is dramatically modified, leading to the change in breakdown strength. [ABSTRACT FROM AUTHOR]

Published

2016