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Figure 134 —Flow past an elliptic cylinder ( a = 90 degrees) 200 



Figure 135 — Calculated pressure shown on an elliptic cylinder 201 



Figure 136 — Flow past a plane lamina 205 



Figure 137 — Flow past a plane lamina 206 



Figure 138 — Flow net around a plane lamina 207 



Figure 139 — Diagram forparabolic coordinates 208 



Figure 140 — Flow past a parabolic cylinder 210 



Figure 141 - Illustration for a circular arc 211 



Figure 142 — Examples of a symmetrical circular-arc cylinder and groove 213 



Figure 143 — Streamlines past a symmetrical circular-arc cylinder 215 



Figure 144 — Streamlines near a thin sheet 215 



Figure 145 - Flow past a sheet or wall 218 



Figure 146 — Flow past two similar cylinders in contact 219 



Figure 147 - Streamlines past a circular cylinder resting against a plane wall 220 



Figure 148 — Streamlines around a circular cylinder attached to a 



semi-infinite plane 223 



Figure 149 - Flow past a right-angle ^ 224 



Figure 150 — Streamlines past an angle-lamina AB 224 



Figure 151 - Two equal line dipoles with longitudinal axes 220 



Figure 152 — Streamlines on one side of the plane of symmetry due to dipoles 227 



Figure 153 - Some possible forms for the dividing surface due to dipoles 227 



Figure 154 - Two equal line dipoles with transverse axes 229 



Figure 155 — Streamlines above the plane of symmetry due to dipoles 230 



Figure 156 - Two possible forms of the dividing surface for two equal 



line dipoles 231 



Figure 157 - Streamlines above the plane of symmetry, outside the 



dividing surface due to dipoles 232 



Figure 158 — Two circular cylinders in a stream 233 



Figure 159 - Streamlines for flow in two directions past two equal circular 



cylinders 234 



Figure 160 — Two slender circular cylinders in motion 236 



Figure 161 - Force due to acceleration of another slender cylinder 239 



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