Hasil Perhitungan Persentase Distribusi Tegangan

49  Lanjutan Tabel 4.12 NO Isolator Terpolusi ke-n Faktor Koreksi δ Tegangan Tembus Bola Keadaaan Standar V s = V p δ kV V V 1 V 2 V 3 V 4 V 5 3 Isolator 5,4,dan 3 0.95 7.98 16.02 23.01 27.98 31.23 34.67 4 Isolator 5,4,3,dan 2 0.95 7.87 16.02 19.87 23.71 27.91 31.87 5 Ke lima Isolator 0.95 8.20 12.31 16.91 20.27 24.36 28.21

IV.3 Hasil Perhitungan Persentase Distribusi Tegangan

Nilai persentase distribusi tegangan pada tiap isolator piring kaca ditentukan berdasarkan persamaan dibawah ini :  � �1 = � 1 −� � � � −� � �100 4.1  � �1 + � �2 = � 2 −� � � � −� � �100 4.2  � �1 + � �2 + � �3 = � 3 −� � � � −� � �100 4.3  � �1 + � �2 + � �3 + � �4 = � 4 −� � � � −� � �100 4.4  � �5 = 100 − � �1 + � �2 + � �3 + � �4 4.5 50 Keterangan: V i1 = Persentase distribusi tegangan posisi 1 dari kawat fasa V i2 = Persentase distribusi tegangan posisi 2 dari kawat fasa V i3 = Persentase distribusi tegangan posisi 3 dari kawat fasa V i4 = Persentase distribusi tegangan posisi 4 dari kawat fasa V i5 = Persentase distribusi tegangan posisi 5 dari kawat fasa  Hasil Perhitungan Persentase Distribusi Tegangan Kondisi Normal  � �1 = 16.09 −8.20 46.05 −8.20 x100 = ��. ��  � �2 = 23,49 −8.20 46.02 −8.20 �100 − 20.85 = ��. ��  � �3 = 30,66 −8.20 46.02 −8.20 �100 − 20.85 + 19.26 = ��. ��  � �4 = 38,03 −8.20 46.02 −8.20 �100 − 20.85 + 19.26 + 18.94 = ��. ��  � �5 = 100 − 20.85 + 19.26 + 18.94 + 21.16 = ��. �� 51 Tabel 4.13 Hasil Perhitungan Persentase Distribusi Tegangan Kondisi Isolator Terpolusi NaCl NO Isolator Terpolusi ke – n Bobot Polusi Ringan Sedang Berat V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 1 5 21.8 16.0 18.4 23.1 20.7 22.5 19.1 18.7 22.1 17.7 23.7 21.2 19.2 19.9 16 2 5 dan 4 22.4 16.9 19.5 20.8 20.3 25.2 20.9 20.4 21.8 14.6 25.8 23.7 21.5 15.5 13.6 3 5,4,dan 3 25.1 18.6 16.6 20.4 19.3 27.6 23.2 17.8 17.7 13.7 28.4 26.5 13.5 17.6 14 4 5,4,3,dan 2 27.1 17.1 16.4 19.9 19.5 29.4 19.9 16.2 17.4 13.5 33.6 13.9 16.1 19.8 16.7 5 Kelima Isolator 24.3 20.9 16.5 19.8 18.8 26.7 19.8 18.2 18.6 16.7 22.9 19.6 22.9 18.3 18.8 Tabel 4.14 Hasil Perhitungan Persentase Distribusi Tegangan Kondisi Isolator Terpolusi CaCO 3 NO Isolator Terpolusi ke – n Bobot Polusi Ringan Sedang Berat V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 1 5 21.9 20.4 19.4 20.8 17.5 23.2 22.0 20.0 23 14.5 26.4 24.6 24.9 22.7 8.9 2 5 dan 4 22.4 21.1 20.2 19.0 17.2 26.1 25.9 23.5 13.9 10.7 29.4 27.5 27.8 7.7 7.6 3 5,4,dan 3 24.1 22.8 17.5 19.0 16.7 28.9 27.2 13.8 13.8 12.5 33.4 30.5 10.6 15.9 9.5 4 5,4,3,dan 2 26.8 19.2 17.4 20.2 16.4 32 16 19.7 16.2 16.3 40.9 14.3 13.6 14.8 16.4 5 Kelima Isolator 21.6 17.0 20.1 20.8 20.5 18.5 20.5 20.4 22.7 17.9 16.1 22.1 18.7 20.9 22.3 52 Tabel 4.15 Hasil Perhitungan Persentase Distribusi Tegangan Kondisi Isolator Terpolusi C NO Isolator Terpolusi ke – n Bobot Polusi Ringan Sedang Berat V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 V 1 V 2 V 3 V 4 V 5 1 5 22.0 21.1 21.1 19.4 16.5 23.3 20.5 19.6 23.6 13.1 24.8 21.6 22.1 25.3 5.9 2 5 dan 4 22.9 22 22 17.9 15.3 24.1 22 21 19.3 13.6 26.6 23.5 24 12.8 12.8 3 5,4,dan 3 25.1 23.7 19.8 16.2 15.2 27.2 24.4 17.3 17.4 13.9 30.1 26.2 18.6 12.2 12.9 4 5,4,3,dan 2 26.7 18.1 19.6 19.3 16.3 31.3 20 18.2 15.4 15.1 34 16 16 17.5 16.5 5 Kelima Isolator 23.4 18 18.6 20.3 19.6 26.1 18.8 21.4 18.6 15.4 20.6 23 16.8 20.4 19.4

IV.4 Analisis Bobot Polusi Masing-Masing Polutan