Question 11 Water is flowing through a 10-cm-diameter water pipe at a rate of 0.2 m3/s....
Question 11 Water is flowing through a 10-cm-diameter water pipe at a rate of 0.2 m3/s. Now a diffuser with an outlet diameter of 20 cm is bolted to the pipe in order to slow down water that exits into atmosphere, as shown. Disregarding frictional effects, determine the force exerted on the flange due to the water flow. Density of water = 1000 kg/m3 -. + d = 10 cm D = 20 cm Diffuser 357 N 1549 N 6205...
Water is flowing through a 10-cm diameter water pipe at a rate
of 0.2 m^3/s. Now a diffuser with an outlet diameter of 20 cm is
bolted to the pipe in order to slow down water that exits into the
atmosphere, as shown. Disregarding frictional effects, determine
the force exerted on the flange due to the water flow. Density of
water = 1,000 kg/m^3.
+ d = 10 cm D = 20 cm Diffuser
Water is flowing through a 10-cm-diameter water pipe at a rate of 0.1 m/s. Then, a diffuser with an outlet diameter of 20 cm is bolted to the pipe in order to slow down water as it exits the diffuser to atmospheric pressure, as shown in the given figure. Disregarding frictional effects, determine the force exerted on the bolts due to the water flow. Take the density of water to be 1000 kg/m3 -t- d 10 cmm D = 20...
CE 2200 Fall 2018 Homework #12 72.22/100 Total points awarded Help Exit ter is flowing through a 10-cm-diameter water pipe at a rate of 01 m3/s. Then, a diffuser with an outlet diameter of 20 cm is to the pipe in order to slow down water as it exits the diffuser to atmospheric pressure, as shown in the given figure. effects, determine the force exerted on the bolts due to the water flow. Take the density of water to be...
3. Water at 10°C (p=999.7kg/m3 and p=1.307x10-3 kg/m.s) is flowing steadily through a 0.2-cm diameter and 15m long pipe at an average velocity of 1.2m/s. . Determine the friction factor . A) 0.035 . B) 0.005 . C) 0.017 . D) 0.0005 . Calculate Re. f = 64/Re
H2.3 Consider water at 20°C flowing through a horizontal pipe of diameter 15 cm and length 10 m. The flowrate is 0.021 m3/s and the wall shear stress is 5.76 N/m2. Assume fully developed flow. a. Verify that the flow is turbulent b. Determine the pressure drop [N/m2 c. Estimate the viscous sublayer thickness [mm], i.e., where y+ 5 d. Compare results of part c. with typical pipe roughness (see Table 8.1 in text and comment on implication e. Using...
also need direction of resultant force
FIGURE P6-37 6-38 Water flowing in a horizontal 25-cm-diameter pipe at 8 m/s and 300 kPa gage enters a 90 bend reducing section, which connects to a 15-cm-diameter vertical pipe. The inlet of the bend is 50 cm above the exit. Neglecting any frictional and gravitational effects, determine the net resultant force exerted on the reducer by the water. Take the momentum- flux correction factor to be 1.04. 6 30 A horizontal 4-cm-diameter water...
Q 14.14: Water is flowing through a pipe of inner diameter 1.6 cm and length 12 m at a speed of 4.3 m/s. If the pipe is at a height of 5.2 m, what is the gravitational potential energy density of the water? A 51000 J/m3 B 98000 J/m3 C 45J/m3 D 0.15J/m3 E 9200 J/m3
1. Water is flowing in a pipe as shown in the figure. The diameter of the cross section area A1 is twice the diameter of A2. The velocity of flow v1 is 2.00m/s while h and h2 are 5.00 cm and 30.0 cm, respectively. Take the density of water to be 1000. kg/m3 (a) Find v2 (b) Calculate the pressure difference P P2 between the two ends of the pipe 2
(15 points) Please show your work! Water (p = 1000 kg/m3) flows through the pipe below. The pressure at point A is 300 kPa. Determine the x and y components of force the water exerts on the horizontal assembly. The pipe has a diameter of 2.5 cm at A, and at B and C the diameter is 1 cm. The water is discharged into the atmosphere at B and C. Neglect frictional losses. Dc = 1 cm A B Da...