3. A hydrant connected to an end of pipe from a water tower. The hydrant is...
3. A hydrant connected to an end of pipe from a water tower. The hydrant is placed at H-18.0m high from the free surface in the tower. The head loss of both the pipe and the hydrant is 5.0m. Find how high the jet issuing from the hydrant can reach. (10 points) Fig. Queation 3
The figure below shows a condenser/cooling tower pipe system needed to remove heat from a water cooled refrigeration condenser and reject the heat to the atmosphere. The amount of heat to be rejected to the atmosphere is 480,000 Btu/hr. The water enters the condenser at 85"F, and the temperature rise of the water through the condenser is 10°F. The total length of the piping in the system is 60 ft. Fittings are as shown. Assume bends to be as shown...
Water is to be delivered from a reservoir through a pipe to a lower level and discharged into the air, as shown in Fig. 7-23. For the data given in the figure, find the vertical distance between the point of water discharge and the water surface in the reservoir. Ans. 12.11 m 50-mm diameter pipe -0.00631 m 11.58 m Fig. 7-23 The pressure inside the pipe at S must not fall below 23.9 kPa absolute. Neglecting losses, how high above...
Problem 1. Water flows from a large tank through a smooth pipe of length 80 m. Both the tank free surface and jet exit are exposed to the atmosphere. Take the density of water p = 1000 kg/m3, dynamic viscosity of water u = 0.001 kg/m.s, atmospheric pressure = 100 kPa, and gravity = 9.8 m/s2. Calculate the volumetric flow rate through the pipe. Neglect entrance losses to the pipe. Hint: Consider the inlet and outlet sections of the pipe...
Problem 1. Water flows from a large tank through a smooth pipe of length 80 m. Both the tank free surface and jet exit are exposed to the atmosphere. Take the density of water p = 1000 kg/m3, dynamic viscosity of water j = 0.001 kg/m.s, atmospheric pressure = 100 kPa, and gravity = 9.8 m/s2. Calculate the volumetric flow rate through the pipe. Neglect entrance losses to the pipe. Hint: Consider the inlet and outlet sections of the pipe...
2. (20 points) The pump shown in the figure pumps 1.5ft/s of water from the reservoir with H-50ft. The head loss associated with this flow is 10ft. Specific weight of water y equals 62.41b/ft';g 32.2ft/s2. The pipe diameter is constant and equals D' C2 iches) . Compute the power in horsepower necessary to run the pump. . Sketch the energy and the hydraulic grade line. free jet
Water is pumped from a well to a water tower (an above-ground reservoir) through a 330 ft long galvanized iron pipe (ε-0.0005 ft) with a 2-in diameter. The water surface in the well is 10 ft below the ground and the water surface in the tower is 60 ft above the ground. The water is to be delivered at a rate of at least 370 L/min. The sum of the minor loss coefficients is 2.1 a) Using the pump performance...
7.14 The pump in Fig. 7.20 delivers water from the lower to the upper reservoir at the rate of 0.057 m3/s. The energy loss between the suction pipe inlet and the pump is 1.83 m and that between the pump outlet and the upper reservoir is 3.66 m. Both pipes are 6-in Schedule 40 steel pipe. Calculate (a) the pressure at the pump inlet, (b) the pressure at the pump outlet, (c) the total head on the pump, and (d)...
Question D.1 A2 Not sure Water flows between two tanks connected by a 100 m long pipe as shown in figure D1-1 below The tanks have a free surface height difference of 15 m and are both open to atmosphere. The first 30 m of pipe from the upper tank (section 1) has an internal diameter of 50 mm and a friction factor of 0.006, whilist the remaining 70m of pipe (section 2) has an internal diameter mm and a...
A pipe system carries water from a reservoir and discharges it as a free jet, as shown. The system consists of piping made from 200-mm diameter commercial steel pipe with two 90 deg elbows with K -0.4m and an inlet minor loss Kl = 0.05 1) (4 pts) Assuming ideal fluid model within the reservoir, show that pressure at point A is VA PA = Pamb +(30 m) - and draw on the diagram the streamline you used. TOT