Water flows in a channel with uniform curvature R. The channel has height h=ℎ=4mm and width w=200mm (normal to the drawing plane) as shown in Fig Q3. The curved part of the channel has a length of l=115mm in the x-direction. You can assume that the channel height is very small compared to the curvature radius.
Neglect effects of gravity.

Fig Q3: Geometry of curved channel, drawing not to scale. The curvature of the channel is not shown, as too small to be drawn accurately at this scale.

Work to 4 significant digits. Enter all values using base units or their combinations, i.e. m, m/s, Pa, N. Do not use multiples as e.g. mm, kPa.

You can use values with exponents, such as 0.12e3.

Transcribed Image Text:

= Water flows in a channel with uniform curvature R. The channel has height h 4 mm and width w=200 mm (normal to the drawing plane) as shown in Fig Q3. The curved part of the channel has a length of 1=115 mm in the x-direction. You can assume that the channel height is very small compared to the curvature radius. Neglect effects of gravity. channel V X 1 lower wall h upper wall centreline Fig Q3: Geometry of curved channel, drawing not to scale. The curvature of the channel is not shown, as too small to be drawn accurately at this scale. Work to 4 significant digits. Enter all values using base units or their combinations, i.e. m, m/s, Pa, N. Do not use multiples as e.g. mm, kPa. You can use values with exponents, such as 0.12e3.

Transcribed Image Text:

b) Your team agree that, from experience, the average velocity of the fluid is v = 48. Assuming that the velocity is uniform S across the channel, and neglecting gravitational effects, determine the curvature R required to generate this force with this flow velocity. Use a sign convention that a positive value indicates that the centre of the radius is above the channel, i.e. the middle of the channel is bent downwards. A negative radius indicates the middle of the channel is bent upwards. The curvature radius R is m.