TY - JOUR
T1 - Reliability verification and optimization of split-type load tap changer structure
AU - Li, Yuanqi
AU - Ge, Yining
AU - Wang, Li
AU - Shao, Yuhang
AU - Li, Jinzhong
AU - Wang, Ke
AU - Liu, Xuandong
AU - Li, Gang
AU - Li, Geqi
N1 - Publisher Copyright:
© 2025, Editorial Department of Electric Machines and Control. All rights reserved.
PY - 2025
Y1 - 2025
N2 - The on-load tap changer (OLTC) has a risk of electrical faults during switching, potentially leading to accidents. A new split-type design was proposed, in which the switching oil chamber is isola-ted from the transformer body, theoretically reducing the likelihood of explosions. To validate this design-particularly the reliability of key isolation structures such as the lead bushing under are fault condi-tions a simulation model was developed using pressure-acoustic and acoustic-structural coupling meth-ods. The effects of fault energy, fault location, and extreme scenarios where the are fault impacts the iso-lation structure near the lead bushing were analyzed. The results show that increased fault energy and a fault source located further from the pressure relief device lead to higher pressure inside the split oil tank. The auxiliary oil tank provides effective protection for the main tank. In extreme cases, the lead bushing remains reliable, but regions such as the oil chamber base and tank connections are prone to stress con-centration and potential damage. Based on these findings, structural optimization is shown to improve stress distribution.
AB - The on-load tap changer (OLTC) has a risk of electrical faults during switching, potentially leading to accidents. A new split-type design was proposed, in which the switching oil chamber is isola-ted from the transformer body, theoretically reducing the likelihood of explosions. To validate this design-particularly the reliability of key isolation structures such as the lead bushing under are fault condi-tions a simulation model was developed using pressure-acoustic and acoustic-structural coupling meth-ods. The effects of fault energy, fault location, and extreme scenarios where the are fault impacts the iso-lation structure near the lead bushing were analyzed. The results show that increased fault energy and a fault source located further from the pressure relief device lead to higher pressure inside the split oil tank. The auxiliary oil tank provides effective protection for the main tank. In extreme cases, the lead bushing remains reliable, but regions such as the oil chamber base and tank connections are prone to stress con-centration and potential damage. Based on these findings, structural optimization is shown to improve stress distribution.
KW - arc fault
KW - distribution of pressure
KW - distribution of stress
KW - finite element simulation
KW - On-load tap changer
KW - separate arrangement
UR - https://www.scopus.com/pages/publications/105018462743
U2 - 10.15938/j.emc.2025.07.002
DO - 10.15938/j.emc.2025.07.002
M3 - 文章
AN - SCOPUS:105018462743
SN - 1007-449X
VL - 29
SP - 12
EP - 21
JO - Dianji yu Kongzhi Xuebao/Electric Machines and Control
JF - Dianji yu Kongzhi Xuebao/Electric Machines and Control
IS - 7
ER -