![Table 2 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar Table 2 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/3c9216e74ae9c7b4a12e3af5ca90ae8af128e6ea/5-Table2-1.png)
Table 2 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar
![Table III from Insulating liquids breakdown voltage determination: Test method efficiency | Semantic Scholar Table III from Insulating liquids breakdown voltage determination: Test method efficiency | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/d01c4856b351d0438d25c31915e474bc37e620b2/3-TableIII-1.png)
Table III from Insulating liquids breakdown voltage determination: Test method efficiency | Semantic Scholar
![Table 3 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar Table 3 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar](https://d3i71xaburhd42.cloudfront.net/3c9216e74ae9c7b4a12e3af5ca90ae8af128e6ea/5-Table3-1.png)
Table 3 from A method for breakdown voltage prediction of short air gaps with atypical electrodes | Semantic Scholar
![SOLVED: TABLE 26.1 Approximate Dielectric Constants and Dielectric Strengths of Various Materials at Room Temperature Dielectric Dielectric Strength" Material Constant K (106 V /m) Air (dry) 1.000 59 Bakelite 4.9 24 Fused SOLVED: TABLE 26.1 Approximate Dielectric Constants and Dielectric Strengths of Various Materials at Room Temperature Dielectric Dielectric Strength" Material Constant K (106 V /m) Air (dry) 1.000 59 Bakelite 4.9 24 Fused](https://cdn.numerade.com/ask_images/8ce251ea081b47e99efb8cf690c984be.jpg)