Question 10 (1 point) Water flows in the horizontal pipe shown in the figure. In Α....
Water flows in the horizontal pipe shown in the figure. At point A the area is 26.0 cm2 and the speed of the water is 2.20 m/s. At B the area is 15.0 cm2. The fluid in the manometer is mercury, which has a density of 13,600 kg/m3. We can treat water as an ideal fluid having a density of 1000 kg/m3. What is the manometer reading h? Question 10 (1 point) Water flows in the horizontal pipe shown in...
A U-tube open at both ends is partially filled with water (see figure) (Pair 1.29 kg/m ) Oil having density 725 kg/m2 is then poured into the right arm and forms a column L = 5.58 cm high. Shield Po Water Oil a) Determine the difference h in heights of the two liquid surfaces. Number Units b)The right arm is then shielded from any air motion while air is blown across the top of the left arm until the surface...
(3) (20%) (a) Name 3 applications of the Bernoulli's Principle. (b) Water flows in the horizontal pipe shown in the following figure. At A the area is 25 cm2 and the speed of the water is 5 m/s. At B the area is 10.0 cm The fluid in the manometer is mercury, which has a density of 13600 kg/m2. What is the manometer reading h? P (S)
8. (10 points extra credit) Consider the figure shown below. It shows a U-shaped mercury manometer (a device for detecting pressure differences) that is attached to a pipe along which water is flowing from left to right. The water pipe has a circular cross-section. At A the diameter of the water pipe is 5.6 cm and the speed of the water is 2.80 m/s. At B the diameter of the pipe is 3 cm. The fluid in the manometer is...
Water flows through a pipe reducer as shown in the figure. If the manometer reading h - 2 m. Find the flow rate in Liters per second. Assume DI-15 cm, D2-10 cm. SG:-0.80 a. What is the effect of the angle θ b. Is this a practical arrangement, if yes why, if not how would you improve it? c. Ca n mercury be used as a manometer fluid in this arrangement? Why, or why not? SG D2 Water Di Water...
Consider a pipe system as shown in Figure 1. The pipe is connected to a mercury manometer at point 1 and point 2. Prove that the pipe wall between these points is exerting less than 600 N of fluid force. The frictional losses along the pipe is not negligible. Water 1.5 m 1 0.15 m 2 30° 0.15 m Mercury,SG 13.5
In a section of horizontal pipe with a diameter of 4.0 cm, the pressure is 47 kPa and water is flowing with a speed of 2.0 m/s. The pipe narrows to 2.0 cm. What is the pressure in the narrower region? Treat the water as an ideal incompressible fluid. The density of water is 1000 kg/m3 . (1 kPa = 1000 Pa)
HELP ME URGENT! Consider a pipe system as shown in Figure 1. The pipe is connected to a mercury manometer at point 1 and point 2. Prove that the pipe wall between these points is exerting less than 600 N of fluid force. The frictional losses along the pipe is not negligible. Water 1.5 m 1 0.15 m 2 30° 0.15 m Mercury,SG 13.5 Figure 1 Question 1
Water flows steadily from a large tank as shown in the figure. The height of water in the tank is H = 4 m represents the height from the centerline of the horizontal pipe to the surface of the water in the tank. The water flows out of the tank through a pipe with diameter of 4 cm. The stream of water flows through a bend (= 30 degrees, L = 2.88 m) and exits as a free jet through...
Water flowing out of a horizontal pipe emerges through a nozzle. The radius of the pipe is 1.7 cm, and the radius of the nozzle is 0.49 cm. The speed of the water in the pipe is 0.78 m/s. Treat the water as an ideal fluid, and determine the absolute pressure of the water in the pipe. Pa