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VSC-HVDC transmission line fault location based on transient characteristics

Yanxia Zhang Anlu Bi Jian Wang Fuhe Zhang Jingyi Lu
Archives of Electrical Engineering | 2021 | vol. 70 | No 2 | 381-398 | DOI: 10.24425/aee.2021.136991
Keywords characteristic roots fault location identification of fault stages Prony algorithm VSC-HVDC
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Abstract

Accurate and reliable fault location is necessary for ensuring the safe and reliable operation of the VSC-HVDC transmission system. This paper proposed a single-terminal fault location method based on the fault transient characteristics of the two-terminal VSCHVDC transmission system. The pole-to-pole transient fault process was divided into three stages, the time-domain expression of the DC current during the diode freewheel stage was used to locate the fault point, and a criterion for judging whether the fault evolves to the diode freewheel stage was proposed. Taking into account the enhancing effect of the opposite system to the fault current, theDCside pole-to-ground fault networkwas equated to a fourth-order circuit model, the relationship of fault distance with the characteristic roots of fault current differential equationwas derived, and the Prony algorithmwas utilized for datafitting to extract characteristic roots to realize fault location. A two-terminal VSC-HVDC transmission system was modelled in PSCAD/EMTDC. The simulation result verifies that the proposed principle can accurately locate the fault point on the VSC-HVDC transmission lines.
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Bibliography

[1] Flourentzou N., Agelidis V.G., Demetriades G.D., VSC-Based HVDC Power Transmission Systems: An Overview, IEEE Transactions on Power Electronics, vol. 24, no. 3, pp. 592–602 (2009).
[2] Li C., Li Y., Guo J., Research on emergency DC power support coordinated control for hybrid multiinfeed HVDC system, Archives of Electrical Engineering, vol. 69, no. 1, pp. 5–21 (2020).
[3] Banu G., Suja S., Fault location technique using GA-ANFIS for UHV line, Archives of Electrical Engineering, vol. 63, no. 2, pp. 247–262 (2014).
[4] Yang L., Wang B., Dong X., Overview of fault location methods in high voltage direct current transmission lines, Automation of Electric Power Systems, vol. 42, no. 8, pp. 185–191 (2018).
[5] Jamali S., Mirhosseini S.S., Protection of transmission lines in multi-terminal HVDC grids using travelling waves morphological gradient, International Journal of Electrical Power and Energy Systems, vol. 108, pp. 125–134 (2019).
[6] Fan Ch., Jiang J., GuoY., Development and applications of travelingwave fault location on transmission lines, Proceedings of the CSU-EPSA, vol. 29, no. 4, pp. 129–134 (2017).
[7] Li D., Ukil A., Satpathi K., Improved S Transform Based Fault Detection Method in VSC Interfaced DC System, IEEE Transactions on Industrial Electronics, vol. 68, iss. 6, pp. 5024–5035 (2020), DOI: 10.1109/TIE.2020.2988193.
[8] Qin J., Peng L.,Wang H., Single terminal methods of traveling wave fault location in transmission line using wavelet transform, Automation of Electric Power Systems, vol. 29, no. 19, pp. 62–65+86 (2005).
[9] Xu X., Sheng G., Liu Y., Fault location method for transmission lines based on distributed traveling wave detection, Proceedings of the Chinese Society of Universities for Electric Power System and its Automation, vol. 24, no. 3, pp. 134–138 (2012).
[10] He Z., Liao K., Li X., Lin S., Yang J., Mai R., Natural Frequency-Based Line Fault Location in HVDC Lines, IEEE Transactions on Power Delivery, vol. 29, no. 2, pp. 851–859 (2014).
[11] He Z., Liao K., Natural frequency-based protection scheme for voltage source converter-based highvoltage direct current transmission lines, IET Generation, Transmission and Distribution, vol. 9, no. 13, pp. 1519–1525 (2015).
[12] Cai X., Song G., Gao S., A novel fault-location method for VSC-HVDC transmission lines based on natural frequency of current, Proceedings of the CSEE, vol. 31, no. 28, pp. 112–119 (2011).
[13] Zhang Y., Wang H., Li T., Combined single-end fault location method for LCC-VSC hybrid HVDC transmission lines, Automation of Electric Power Systems, vol. 43, no. 21, pp. 187–199 (2019).
[14] Suonan J., Gao S., Song G., Jiao Z., Kang X., A Novel Fault-Location Method for HVDC Transmission Lines, IEEE Transactions on Power Delivery, vol. 25, no. 2, pp. 1203–1209 (2010).
[15] Yanxia Z., JianW., Huilan J., Fang Z., A Novel Fault Location Method for Hybrid-HVDC Transmission Line, 2019 IEEE Power and Energy Society General Meeting (PESGM), Atlanta, GA, USA, pp. 1–5 (2019).
[16] Song G., Zhou D., Jiao Z., A novel fault location principle for HVDC transmission lines, Automation of Electric Power Systems, vol. 31, no. 24, pp. 57–61 (2007).
[17] Kang L., Tang K., Luo J., Two-terminal fault location of monopolar earth fault in HVDC transmission lines, Power System Technology, vol. 38, no. 8, pp. 2268–2273 (2014).
[18] JinY., Fletcher J.E., O’Reilly J., Short- circuit and ground fault analyses and location in VSC-based DC network cables, IEEE Transactions on Industrial Electronics, vol. 59, no. 10, pp. 3827–3837 (2012).
[19] Liu D., Wei T., Huo Q., DC side line-to-line fault analysis of VSC-HVDC and DC-fault-clearing methods, 2015 5-th International Conference on Electric Utility Deregulation and Restructuring and Power Technologies (DRPT), Changsha, China, pp. 2395–2399 (2015).
[20] Dessouky S.S., Fawzi M., Ibrahim H.A., Ibrahim N.F., DC Pole to Pole Short Circuit Fault Analysis in VSC-HVDC Transmission System, 2018 Twentieth International Middle East Power Systems Conference (MEPCON), Cairo, Egypt, pp. 900–904 (2018).
[21] Ke J., Meng L.I., Shu B.T., A voltage resonance-based single-ended online fault location algorithm for DC distribution networks, Sciences China Technological Sciences, vol. 59, no. 5, pp. 721–729 (2016).
[22] Hwang K.S., Chang F.C., Chiou J.Y., A numerical approach to fast evaluation of time-invariant system responses, International Journal of Computer Mathematics, vol. 73, no. 3, pp. 361–369 (2000).
[23] Liu D., HuW., Chen Z., SVD-TLS extending Prony algorithm for extracting UWB radar target feature, Journal of Systems Engineering and Electronics, vol. 19, no. 2, pp. 286–291 (2008).
[24] Xu M.M., Xiao L.Y.,Wang H.F., A prony-based method of locating short-circuit fault inDCdistribution system, 2-nd IETRenewable Power Generation Conference (RPG 2013), Beijing, China, pp. 1–4 (2013).
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Authors and Affiliations

Yanxia Zhang
1
Anlu Bi
1
Jian Wang
1
Fuhe Zhang
1
Jingyi Lu
1
  1. School of Electrical and Information Engineering, Tianjin University, China

Application of Weathered Granulated Blast Furnace Slag as a Supplementary Cementitious Material in Concrete

Wiktor Pacierpnik Wiesława Nocuń-Wczelik Ewa Kapeluszna
Archives of Civil Engineering | Vol. 66 | No 4 | 381-398 | DOI: 10.24425/ace.2020.135227
Keywords supplementary cementing materials (SCMs) old slag slag weathering compressive strength heat of hydration microstructure
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Abstract

The physical and chemical properties of cements with slag originated from the storage yards of different age, added as a supplementary cementing material are highlighted. The materials after 20-year storage, the crushed slag after approximately 2-year storage and the new slag from the ongoing production were compared. The materials supplied by the same metallurgical plant were characterized. The blended cements were produced by Portland cement clinker grinding with gypsum and slags added as 5 to 50% of binder mass. The standard properties of cements were examined, as well as some experiments related to the kinetics of hydration and hydration products were carried out. The addition of granulated blast furnace slag (GBFS) stored for a long time, as a component of cement, affects the properties of material in such a way that the early compressive strength is not specially altered but at longer maturing the strength decreases generally with the storage time and percentage of additive. This is related to the reduction of the vitreous component, as well as to the presence of weathered material of altered activity. At the additive content up to 50% the binder complying with the requirements of the European standards for CEM III/A or CEM II/(A,B)-S common cements can be produced. The cements with the old slag meet the requirements of EN 197-1 relating at least to the class 32,5. The role of calcium carbonate, being the product resulting from the slag weathering process, acting as a grindability and setting/hardening modifying agent, should be underlined.

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Authors and Affiliations

Wiktor Pacierpnik
Wiesława Nocuń-Wczelik
Ewa Kapeluszna

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