2.
At one point in a pipeline the water’s speed is 3.00 m/s and the gauge pressure is 5.00∙104 Pa. Find the gauge pressure at a second point in the line, 11.0 m lower than the first, if the pipe diameter at the second point is twice that at the first.
Note: density of water is 1000 kg/m3.
2. At one point in a pipeline the water’s speed is 3.00 m/s and the gauge...
At one point in a pipeline the water’s speed is 3.00 m/s and the gauge pressure is 5.00∙104 Pa. Find the gauge pressure at a second point in the line, 11.0 m lower than the first, if the pipe diameter at the second point is twice that at the first.Note: density of water is 1000 kg/m3.
1. At one point in a pipeline the water's speed is 3.00 ms and the gauge pressure is 5.00 x 104 Pa. Find the gauge pressure at a second point in the line, 11.0 m lower than the first, if the pipe diameter at the second point is twice that at the first.
6. Fluids (16 points). At one point in a vertical pipeline the water s d is 3.00 m/s and the pressure is the line, 12.0 m lower than the first, the diameter of the pipe is at the first (Pwater 1000 kg/m3 the second point. (b, points) Find the pressure at the second point. 5.00 × 105 Pa. At a second point in twice that kg/m3). ( a, 8 points) Find the water's speed at
At one point in a pipeline the water's speed is 3.00m/s and the gauge pressure is 5.00×104Pa Find the gauge pressure at a second point in the line, 11.0m lower than the first, if the pipe diameter at the second point is twice that at the first.
At a certain point in a horizontal pipeline, the water's speed is 3.50 m/s and the gauge pressure is 2.30×104 Pa . Part A Find the gauge pressure at a second point in the line if the cross-sectional area at the second point is twice that at the first. Please shwo all your work.
A brine solution with a density of 1230 kg/m3 moves through a constricted pipe in steady, ideal flow. At the lower point shown in the figure below, the pressure is P1 = 1.95 × 104 Pa, and the pipe diameter is 5.00 cm. At another point y = 0.35 m higher, the pressure is P2 1.00 104 Pa and the pipe diameter is 2.50 cm. P2 (a) Find the speed of flow (in m/s) in the lower section m/s (b)...
Water flows at speed of 6 m/s through a horizontal pipe of diameter 3.5 cm. The gauge pressure P1 of the water in the pipe is 1.7 atm. A short segment of the pipe is constricted to a smaller diameter of 2.4 cm . What is the gauge pressure of the water flowing through the constricted segment? Atmospheric pressure is 1.013 × 10^5 Pa. The density of water is 1000 kg/m^3 . The viscosity of water is negligible. Answer in...
A small plastic pipe carries water horizontally at a speed of 10 m s?1. A section of the pipe bulges out so that the radius is twice that of the rest of the pipe. If the gauge pressure in the pipe is ordi- narily+90 kPa what is the gauge pressure in the bulge (in kPa) (the density of water is 1000 kg m?3)? Give your answer in kPa.
Water moves through a constricted pipe in steady, ideal flow. At the lower point shown in the figure below, the pressure is P1 = 1.70 x 104 Pa, and the pipe diameter is 8.0 cm. At another point y = 0.40 m higher, the pressure is P2 = 1.30 x 104 Pa and the pipe diameter is 4.00 cm. (a) Find the speed of flow in the lower section. m/s (b) Find the speed of flow in the upper section....
What is the gauge pressure (in Pascals) at a depth of 3.13m below the surface of a swimming pool Assume the density of water is 1000 kg/m QUESTION 2 At what depth (in meters) in the ocean is the gauge pressure 10 times larger than atmospheric pressure? Assume that the density of water in the ocean is 1000 kg/m3 and that atmospheric pressure is 101,325 Pa