Abstract
The effects of C=C, ester and β-H groups on the ionization potential (IP) and electron affinity (EA) of molecules in natural ester insulation oil were investigated by density functional theory (DFT). The major contribution to the highest occupied molecular orbital (HOMO) comes from the carbon atoms adjacent to C=C. Thus, the IPs of triglycerides decrease as the number of C=C double bonds increases. The C=C in alkanes may also lower the IP. However, the β-H in triglycerides has little effect on the IP, and C=C and β-H have only a small effect on the EAs of the triglycerides because of the major contributions of atoms near the ester group in triglycerides to the lowest unoccupied molecular orbital (LUMO). This study calculated the IPs of 53 kinds of molecules in FR3, which are significantly lower compared with those of molecules in mineral oil (MO) and trimethylolpropane triester without C=C. However, the lightning impulse breakdown voltage (LI Vb) of trimethylolpropane triester is still significantly lower than that of MO at the large gap. Therefore, the transition from slow to fast streamers under low lighting impulse voltage is determined by the ester group rather than by C=C and β-H. The ester group may attract more electrons, impacting itself more compared to alkane in MO and facilitating the transition from slow to fast streamers.
Highlights
Several billion liters of insulation oils have been widely applied in transformers, resistors, capacitors and thyristors, etc. [1]
As the promising substitutes for MO, natural ester insulation oil (NEO) has several advantages of renewability and biodegradability and less flammability compared with MO [3]
The decrease in triglyceride ionization potential (IP) caused by an increase in DN is not linear
Summary
Several billion liters of insulation oils have been widely applied in transformers, resistors, capacitors and thyristors, etc. [1]. Several billion liters of insulation oils have been widely applied in transformers, resistors, capacitors and thyristors, etc. Mineral insulation oil (MO) is still widely used in transformers, which are highly important in safe power grid operation. To improve the safety and reduce the environmental impact of the transformer, alternative insulation oils are demanded [2]. As the promising substitutes for MO, natural ester insulation oil (NEO) has several advantages of renewability and biodegradability and less flammability compared with MO [3]. NEO is claimed to delay the aging rate of insulation paper and prolong the lifetime of a transformer [4,5,6,7,8,9]
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