Your search keyword '"FU Xiaotao"' showing total 16 results

1. A material balance based practical analysis method to improve the dynamic reserve evaluation reliability of ultra-deep gas reservoirs with ultra-high pressure

Author

Sun, Hedong, Cao, Wen, Li, Jun, Jia, Wei, Li, Yuanjie, Wu, Yan, Zhu, Songbai, Fu, Xiaotao, Yang, Min, and Meng, Guangren

Published

2021

2. Study on the Ageing Characteristics of Silicone Rubber for Composite Insulators under Multi-Factor Coupling Effects.

Author

Li, Xinran, Zhang, Yuming, Chen, Lincong, Fu, Xiaotao, Geng, Jianghai, Liu, Yunpeng, Gong, Yijing, and Zhang, Simin

Subjects

COMPOSITE insulators, SILICONE rubber, ELECTRIC lines, DIELECTRIC loss, SCANNING electron microscopy

Abstract

Due to long-term exposure to high electrical field strength, heavy loads, and the complex climatic conditions in tropical coastal areas of China, widespread abnormal heating phenomena often occur in the operation of composite insulators in power transmission lines, posing a threat to the safe and stable operation of the power system. To study the ageing process of the silicone rubber sheath of composite insulators in the high-field, high-humidity, high-temperature, and high-salt-density environments along the coastal regions, this paper establishes a humidity–heat–electricity–salt spray accelerated ageing test platform and conducts ageing tests on silicone rubber materials for composite insulators under the coupled effect of multiple factors. The ageing characteristics of silicone rubber materials are analyzed using scanning electron microscopy, Fourier infrared spectroscopy, thermogravimetric analysis, and other methods. The results show that the coupled ageing factors have an impact on the surface morphology of silicone rubber. The continuous depolymerization of PDMS molecular chains leads to a decrease in the content of groups related to the hydrophobicity of the material, resulting in a deterioration of its hydrophobicity. Moreover, the degradation of silicone rubber materials and the enhanced moisture absorption capacity lead to an increase in the dielectric loss tangent of the saturated moisture-absorbing medium, thereby causing abnormal heating of the sheath at the end of the composite insulator. The research findings of this study are of significant reference value for revealing the degradation mechanism of composite insulator silicone rubber sheaths in tropical island environments and improving the service life of composite insulators. [ABSTRACT FROM AUTHOR]

Published

2023

3. Study on Deterioration Characteristics of a Composite Crossarm Mandrel in a 10 kV Distribution Network Based on Multi-Factor Aging.

Author

Ma, Long, Fu, Xiaotao, Chen, Lincong, Chen, Xiaolin, Zhang, Cong, Li, Xinran, Li, Wei, Fu, Fangda, Fu, Chuanfu, Lin, Taobei, Mao, Wensheng, and Liu, Hechen

Subjects

*STRAINS & stresses (Mechanics), *ARBORS & mandrels, *FIBER-matrix interfaces, *ELECTRIC insulators & insulation, *SHEAR strength, *MICROCRACKS

Abstract

This paper presents a study that conducted 5000 h of multi-factor aging tests on 10 kV composite crossarms, considering the natural environment in coastal areas and actual power line operations. Various aging conditions, such as voltage, rain, temperature, humidity, salt fog, ultraviolet light, and mechanical stress, were applied during the tests. The research initially analyzed the influence of multi-factor aging on the bending and tensile properties of the full-size composite crossarm. Subsequently, a detailed investigation was carried out to assess the impact of aging on the mechanical properties, electrical insulation properties, and microscopic characteristics of the composite crossarm core bar. Results indicated that the tensile strength and bending strength of the full-size composite crossarm mandrel experienced minimal changes after aging, remaining well within operational requirements. However, the silicone rubber outer sheath's hydrophobicity decreased, leading to the appearance of cracks and holes on the surface, which provided pathways for moisture and salt infiltration into the mandrel. As a consequence, the bending strength and shear strength of the mandrel material were reduced by 16.5% and 37.7%, respectively. Moreover, the electrical performance test demonstrated a slight change in the mandrel's leakage current, while the electrical breakdown strength decreased by 22.8%. Microscopic analysis using SEM, three-dimensional CT, and TGA revealed that a small amount of resin matrix decomposed and microcracks appeared on the surface. Additionally, the fiber-matrix interface experienced debonding and cracking, leading to an increased moisture absorption rate of the mandrel material. [ABSTRACT FROM AUTHOR]

Published

2023

4. Study on Blending Modification of Bisphenol A Epoxy.

Author

Fu, Xiaotao, Ma, Long, Chen, Lincong, Zhang, Cong, Chen, Xiaolin, Li, Xinran, Fu, Fangda, Fu, Chuanfu, Lin, Taobei, and Mao, Wensheng

Subjects

*EPOXY resins, *COMPOSITE insulators, *DIELECTRIC loss, *STRAY currents, *HIGH temperatures

Abstract

Epoxy-resin-based composites in the field of current electrical materials often work in high temperature, high humidity or salt spray conditions. In order to improve the operation reliability of the composite insulator cross arm in a high temperature, high humidity and high salt spray environment, and analyze the aging mechanism and performance characteristics of resin, in this paper, wet heat aging and salt spray aging experiments were carried out on the blended resin system composed of bisphenol A type epoxy resin (E-51), aliphatic epoxy modified bisphenol A epoxy resin (2021P/E-51) and dimeric acid modified bisphenol A epoxy resin (EPD-172/E-51). Among them, 10 wt% and 20 wt% of 2021P blend resin and 10 wt% of EPD blend resin have superior thermo-mechanical properties. Under humid and hot conditions, the dielectric loss of 10 wt% EPD blend system before and after aging is 39.9% and 49.5% lower than that of pure E51 resin system, respectively. Under the condition of salt spray, the dielectric loss of 20 wt% and 10 wt% EPD blends decreased by 73.1% and 74.6% after aging. The leakage current of 10 wt% 2021P blend resin and 10 wt% EPD blend resin decreased by 7% and 3.8% before aging, respectively. After aging, they decreased by 3.7% and 2.2%, respectively. The bending strength of 2021P blend resin before and after aging reached 29.3 MPa and 26.6 MPa, respectively. The above three blending resin systems exhibit good electrical properties and good mechanical properties, their ageing resistance performance is strong and they are suitable as the matrix resin of compound cross arm mandrel material. [ABSTRACT FROM AUTHOR]

Published

2023

5. Effect of Sizing Agent on the Mechanical, Thermal, and Electrical Performance of Basalt Fiber/Epoxy Composites.

Author

Ma, Long, Fu, Xiaotao, Zhang, Cong, Chen, Lincong, Chen, Xiaolin, Fu, Chuanfu, Yu, Yunfei, and Liu, Hechen

Subjects

*BASALT, *EPOXY resins, *GLASS composites, *FIBERS, *FIBROUS composites, *FLEXURAL modulus, *DIELECTRIC loss

Abstract

Basalt fiber and its resin composites have gradually supplanted traditional steel and glass fiber composites due to their superior strength, heat resistance, and corrosion resistance. However, basalt fiber still has significant flaws that restrict the functionality and use of its composites, such as less active functional groups and poor resin adherence. This study examines the effects of sizing agent on the characteristics of basalt fiber/epoxy resin composites. Epoxy resin emulsion and acrylate emulsion are employed as the primary auxiliary film-forming agents in this study. Polyurethane emulsion with various content levels is also used. The findings indicate that a 1% wt. of polyurethane emulsion concentration produces the greatest results, increasing the composite's flexural strength, flexural modulus, tensile strength, and interlaminar shear strength by 122%, 34.0%, 102%, and 10.2%, respectively. At the same time, the storage modulus and Tg of the material will decrease. In addition, the breakdown strength can be raised by 112%, and insulation parameters such as leakage current and dielectric loss factor can be decreased by 26.4% and 15.6%, respectively. The effect of sizing agent B is the best. [ABSTRACT FROM AUTHOR]

Published

2022

6. A Study on the Influence of End-Sheath Aging and Moisture Absorption on Abnormal Heating of Composite Insulators.

Author

Li, Xinran, Zhang, Simin, Chen, Lincong, Fu, Xiaotao, Geng, Jianghai, Liu, Yunpeng, Huang, Qilin, and Zhong, Zheng

Subjects

COMPOSITE insulators, POLAR molecules, HEATING, PERMITTIVITY, SURFACE contamination, DIELECTRIC loss, MOISTURE, DIELECTRIC films

Abstract

Abnormal heating of composite insulators of high-voltage transmission lines concentrate at its end, especially in a high-humidity environment. In order to study the influence of end-sheath aging and moisture absorption on abnormal heating of composite insulators, in this paper, we first discuss the appearance test, temperature rise test, and dielectric characteristic test conducted on 110 kV decommissioned composite insulators. Test results indicated the temperature rise in composite insulators increased with ambient humidity, but temperature rise was not severely affected by surface contamination of its shed and sheath; in dry environments, the dielectric constant and dielectric loss factor of high-voltage end sheaths are higher than of those of medium- and low-voltage end sheaths, and the loss effect becomes more severe after moisture absorption in a high-humidity environment. After the tests, the authors established a COMSOL simulation model of composite insulators, to analyze changes in the electric field and thermal field of the end sheath of composite insulators due to the coupling of electric and thermal fields. It was concluded that the dielectric constant of a high-voltage end sheath of the composite insulator increased after moisture absorption, distorting the partial electric field on the surface; meanwhile, the dielectric loss factor increased significantly after water molecules intruded into the aging layer of the sheath as polar molecules. Therefore, the dielectric loss (leakage conductance loss and lossy polarization loss) caused by aging and moisture absorption of the sheath surface under partially high field strength in the high-humidity environment was the leading cause of abnormal heating at the high-voltage end of composite insulators. The conclusion of this paper serves as an important reference for revealing the causes of abnormal heating of composite insulators in high-humidity environments and the influence mechanism of external factors on abnormal heating. [ABSTRACT FROM AUTHOR]

Published

2022

7. Properties of Basalt Fiber Core Rods and Their Application in Composite Cross Arms of a Power Distribution Network.

Author

Liu, Yunpeng, Zhang, Mingjia, Liu, Hechen, Tian, Lin, Liu, Jie, Fu, Chuanfu, and Fu, Xiaotao

Subjects

POWER distribution networks, FIBERS, FIBROUS composites, BASALT, GLASS fibers, ELECTRIC insulators & insulation, FLEXURAL modulus

Abstract

As basalt fiber has better mechanical properties and stability than glass fiber, cross arms made of continuous basalt-fiber-reinforced epoxy matrix composites are capable of meeting the mechanical requirements in the event of typhoons and broken lines in coastal areas, mountainous areas and other special areas. In this paper, continuous basalt-fiber-reinforced epoxy matrix composites were used to fabricate the core rods and composite cross arms. The results verified that basalt fiber composite cross arms can meet the strict requirements of transmission lines in terms of quality and reliability. In addition to high electrical insulation performance, the flexural modulus and the flexural strength of basalt fiber core rods are 1.8 and 1.06 times those of glass fiber core rods, respectively. Basalt fiber core rods were found to be much better load-bearing components compared to glass fiber core rods. However, the leakage current and the result of scanning electron microscopy (SEM) analysis reveal that the interface bonding strength between basalt fibers and the matrix resin is weak. A 3D reconstruction of micro-CT indicates that the volume of pores inside basalt fiber core rods accounts for 0.0048% of the total volume, which is greater than the 0.0042% of glass fiber rods. Therefore, improving the interface bond between basalt fibers and the resin can further improve the properties of basalt fiber core rods. [ABSTRACT FROM AUTHOR]

Published

2022

8. A Lithium Ion Highway by Surface Coordination Polymerization: In Situ Growth of Metal-Organic Framework Thin Layers on Metal Oxides for Exceptional Rate and Cycling Performance.

Author

Han, Yuzhen, Yu, Danni, Zhou, Junwen, Xu, Peiyu, Qi, Pengfei, Wang, Qianyou, Li, Siwu, Fu, Xiaotao, Gao, Xing, Jiang, Chenghao, Feng, Xiao, and Wang, Bo

Subjects

METAL-organic frameworks, LITHIUM ions, METALLIC oxides, TRANSITION metals, CURRENT density (Electromagnetism)

Abstract

A thin layer of a highly porous metal-organic framework material, ZIF-8, is fabricated uniformly on the surface of nanostructured transition metal oxides (ZnO nanoflakes and MnO2 nanorods) to boost the transfer of lithium ions. The novel design and uniform microstructure of the MOF-coated TMOs (ZIF-8@TMOs) exhibit dramatically enhanced rate and cycling performance comparing to their pristine counterparts. The capacities of ZIF-8@ZnO (nanoflakes) and ZIF-8@MnO2 (nanorods) are 28 % and 31 % higher that of the pristine ones at the same current density. The nanorods of ZIF-8@MnO2 show a capacity of 1067 mAh g−1 after 500 cycles at 1 Ag−1 and without any fading. To further improve the conductivity and capacity, the ZIF-8-coated materials are pyrolyzed at 700 °C in an N2 atmosphere (ZIF-8@TMO-700 N). After pyrolysis, a much higher capacity improvement is achieved: ZIF-8@ZnO-700 N and ZIF-8@MnO2-700 N have 54 % and 69 % capacity increases compared with the pristine TMOs, and at 1 Ag−1, the capacity of ZIF-8@MnO2-700 N is 1060 mAh g−1 after cycling for 300 cycles. [ABSTRACT FROM AUTHOR]

Published

2017

9. Inorganic and organic hybrid solid electrolytes for lithium-ion batteries.

Author

Fu, Xiaotao, Yu, Danni, Zhou, Junwen, Li, Siwu, Gao, Xing, Han, Yuzhen, Qi, Pengfei, Feng, Xiao, and Wang, Bo

Subjects

*ORBITAL hybridization, *SOLID electrolytes, *ELECTRONIC equipment, *ENERGY storage, *LITHIUM-ion batteries

Abstract

Lithium ion batteries (LIBs) have achieved great success in powering portable electronic devices in our modern society, and are to find use in the electrification of transportation and the storage of wind or solar energy in smart grids in the near future. However, there is increasing concern on the safety issues of current LIBs based on organic liquid electrolytes, which are volatile and flammable. This leads to the exploration and development of solid electrolytes to improve the safety of next-generation high-energy LIBs. In this review, we describe two inorganic–organic hybrid solid electrolyte systems for LIBs. Firstly, we present polymer electrolytes with different types of inorganic fillers, discussing how the fillers affect the electrochemical and physical properties of the electrolyte. Secondly, we introduce recent progress in MOF-based solid electrolytes and show how MOFs can contribute to such an inorganic–organic hybrid system. Finally, outlook and future directions for safe and high performance inorganic–organic hybrid solid electrolytes are proposed. [ABSTRACT FROM AUTHOR]

Published

2016

10. An effective approach to improve the electrochemical performance of LiNi0.6Co0.2Mn0.2O2 cathode by an MOF-derived coating.

Author

Li, Siwu, Fu, Xiaotao, Zhou, Junwen, Han, Yuzhen, Qi, Pengfei, Gao, Xing, Feng, Xiao, and Wang, Bo

Abstract

Herein, we report an effective surface modification for a high energy cathode material, LiNi0.6Co0.2Mn0.2O2 (NCM-622), using an Al-based MOF (NH2-MIL-53), as a precursor to produce MOF-derived alumina (MDA) coatings. The MDA-coating (2.5 wt%) is well-dispersed on the surface of NCM-622 with an amorphous structure. By virtue of the MDA-coating, NCM-622 shows greatly enhanced electrochemical performance: 214.6 mA h g−1 and 196.5 mA h g−1 (3.0–4.5 V vs. Li+/Li) at 0.2C and 1C, respectively, with a capacity retention of 92.7% after 100 cycles at 1C; even at high rates of 5C and 10C, the discharge capacity still approaches 168.5 mA h g−1 and 150.0 mA h g−1, respectively. We found that these enhancements can be ascribed to the improved structural stability and electrochemical kinetics of NCM-622 by the MDA-coating. [ABSTRACT FROM AUTHOR]

Published

2016

11. Controllable synthesis of TiO2 nanoparticles employing substrate/dielectrophoresis/sol-gel.

Author

Cui, Chenyang, Chen, Huiying, Zuo, Tongtong, Fu, Xiaotao, Chen, Lizhen, Geng, Junfeng, Li, Hua, and Xing, Xuan

Abstract

Due to size-dependent catalytic selectivity, the size and special morphology are of great importance to applications of TiO2. The synthesis method of size and morphology control has been in need of innovation. In this study, TiO2 nanoparticles(TiO2-NPs) with well-defined morphology and homogenous size were synthesized using a novel method, in which bamboo substrate, dielectrophoresis (DEP) technology and a sol-gel process were combined(substrate/ DEP/ sol-gel). Powder X-ray diffraction (XRD) and scanning electron microscopy (SEM) techniques were used to characterize the TiO2-NPs. Further study showed that, with this combined method, the size and the uniformity of TiO2-NPs can be controlled by changing the voltage of DEP. The number and arrangement of TiO2 nanorods can be controlled by changing the voltage. Substrate/ DEP/ sol-gel proved to be an efficient way to form special morphologies of TiO2-NPs. A visible-light catalytic activity experiment showed that among three preparation methods, the substrate/ DEP/ sol-gel method made TiO2-NPs with the highest catalytic activity for degradation of methyl orange. TiO2-NPs produced by the DEP/ sol-gel process presented higher catalytic activity than TiO2-NPs produced by only a sol-gel process. [ABSTRACT FROM AUTHOR]

Published

2016

12. MOF derived composites for cathode protection: coatings of LiCoO2 from UiO-66 and MIL-53 as ultra-stable cathodes.

Author

Qi, Pengfei, Han, Yuzhen, Zhou, Junwen, Fu, Xiaotao, Li, Siwu, Zhao, Jingshu, Wang, Lu, Fan, Xinxin, Feng, Xiao, and Wang, Bo

Subjects

LITHIUM compounds, COMPOSITE materials research, METALLIC oxides, CATHODES, CHEMICAL research

Abstract

A mechanochemical synthetic method of preparing LiCoO2 coated by MOF-derived metal oxide composites is introduced. Mono-dispersed ZrO2 and Al2O3 are applied as protection layers. These composites show 148 mA h g−1 at a current density of 2325 mA g−1 and excellent thermal stability (55 °C). [ABSTRACT FROM AUTHOR]

Published

2015

13. A Lithium Ion Highway by Surface Coordination Polymerization: In Situ Growth of Metal-Organic Framework Thin Layers on Metal Oxides for Exceptional Rate and Cycling Performance.

Author

Han Y, Yu D, Zhou J, Xu P, Qi P, Wang Q, Li S, Fu X, Gao X, Jiang C, Feng X, and Wang B

Abstract

A thin layer of a highly porous metal-organic framework material, ZIF-8, is fabricated uniformly on the surface of nanostructured transition metal oxides (ZnO nanoflakes and MnO 2 nanorods) to boost the transfer of lithium ions. The novel design and uniform microstructure of the MOF-coated TMOs (ZIF-8@TMOs) exhibit dramatically enhanced rate and cycling performance comparing to their pristine counterparts. The capacities of ZIF-8@ZnO (nanoflakes) and ZIF-8@MnO 2 (nanorods) are 28 % and 31 % higher that of the pristine ones at the same current density. The nanorods of ZIF-8@MnO 2 show a capacity of 1067 mAh g -1 after 500 cycles at 1 Ag -1 and without any fading. To further improve the conductivity and capacity, the ZIF-8-coated materials are pyrolyzed at 700 °C in an N 2 atmosphere (ZIF-8@TMO-700 N). After pyrolysis, a much higher capacity improvement is achieved: ZIF-8@ZnO-700 N and ZIF-8@MnO 2 -700 N have 54 % and 69 % capacity increases compared with the pristine TMOs, and at 1 Ag -1 , the capacity of ZIF-8@MnO 2 -700 N is 1060 mAh g -1 after cycling for 300 cycles., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

14. Metal-Organic Frameworks (MOFs) as Sandwich Coating Cushion for Silicon Anode in Lithium Ion Batteries.

Author

Han Y, Qi P, Zhou J, Feng X, Li S, Fu X, Zhao J, Yu D, and Wang B

Abstract

A novel metal-organic framework (MOF) sandwich coating method (denoted as MOF-SC) is developed for hybrid Li ion battery electrode preparation, in which the MOF films are casted on the surface of a silicon layer and sandwiched between the active silicon and the separator. The obtained electrodes show improved cycling performance. The areal capacity of the cheap and readily available microsized Si treated with MOF-SC can reach 1700 μAh cm(-2) at 265 μA cm(-2) and maintain at 850 μAh cm(-2) after 50 cycles. Beyond the above, the commercial nanosized Si treated by MOF-SC also shows greatly enhanced areal capacity and outstanding cycle stability, 600 μAh cm(-2) for 100 cycles without any apparent fading. By virtue of the novel structure prepared by the MOFs, this new MOF-SC structure serves as an efficient protection cushion for the drastic volume change of silicon during charge/discharge cycles. Furthermore, this MOF layer, with large pore volume and high surface area, can adsorb electrolyte and allow faster diffusion of Li(+) as evidenced by decreased impedance and improved rate performance.

Published

2015

15. MOF derived composites for cathode protection: coatings of LiCoO2 from UiO-66 and MIL-53 as ultra-stable cathodes.

Author

Qi P, Han Y, Zhou J, Fu X, Li S, Zhao J, Wang L, Fan X, Feng X, and Wang B

Abstract

A mechanochemical synthetic method of preparing LiCoO2 coated by MOF-derived metal oxide composites is introduced. Mono-dispersed ZrO2 and Al2O3 are applied as protection layers. These composites show 148 mA h g(-1) at a current density of 2325 mA g(-1) and excellent thermal stability (55 °C).

Published

2015

16. In situ growth of MOFs on the surface of si nanoparticles for highly efficient lithium storage: Si@MOF nanocomposites as anode materials for lithium-ion batteries.

Author

Han Y, Qi P, Feng X, Li S, Fu X, Li H, Chen Y, Zhou J, Li X, and Wang B

Abstract

A simple yet powerful one-pot strategy is developed to prepare metal-organic framework-coated silicon nanoparticles via in situ mechanochemical synthesis. After simple pyrolysis, the thus-obtained composite shows exceptional electrochemical properties with a lithium storage capacity up to 1050 mA h g(-1), excellent cycle stability (>99% capacity retention after 500 cycles) and outstanding rate performance. These characteristics, combined with their high stability and ease of fabrication, make such Si@MOF nanocomposites ideal alternative candidates as high-energy anode materials in lithium-ion batteries.

Published

2015