Consider the flow of oil with a density 894 kg/m3 and viscosity 2.33 kg/ms in a 40-cm-diameter pipeline at an average velocity of 0.5 m/s. A 300-m-long section of the pipeline passes through the icy waters of a lake. Disregarding the entrance effects, the friction factor of flow.
Consider the flow of oil with a density 894 kg/m3 and viscosity 2.33 kg/ms in a...
O 6 Save& Exct Submit 10.00 points Consider the flow of oil with p- 894 kg/m3 and 2.33 kg/m-s in a waters of a lake. Disregarding the entrance effects, determine ppeline at an average velocity of 0.5 ms. A 358-m-long section of the pipeline passes through the icy the pumping power required to overcome the pressure losses and to maintain the flow of oll in the pipe. The pumping power required to overcome the pressure losses and to maintain the...
DON’T disregard the thermal conductivity of the pipe 3.) Oil at 200 C flows in a pipeline. The pipe has a 30-cm diameter and the flow is at an average velocity of 2 m/s. A 200-m-long section of the pipeline passes through icy waters of a lake at 0° C. The pipe is uncoated carbon steel with a thermal conductivity of 61 W/m o C. Determine (a) the temperature of the oil when the pipe leaves the lake, (b) the...
Oil with a density of 850 kg/m and kinematic viscosity of 0.00062 m2/s is being discharged from a 5-mm-diameter, 40-m-longhorizontal pipe from a storage tank open to the atmosphere. The height of the liquid level above the center of the pipe is 3-m. If the friction factor (f) of the pipe is 0.006. Disregarding the minor losses, determine the flow rate of oil through the pipe. 11. 3 m Oil tank 5 mm
1. An oil of density p800 kg/m3 and viscosity u 5 cP flows at 10 liters/min through a 30 m smooth circular pipe of inner diameter 2 cm. It then flows through a filtering section made up of the same pipe packed at void fraction ε-0.4 with solid spherical particles of diameter 0.5 mm to filter out any fine material. All pipe sections are straight as shown. Design constraint: the pressure drop in the packed bed section (call this AP2)...
The density of water is p = 1000 kg and the viscosity is u = 2 kg. Consider diameter of pipe is lm and the velocity of the flow is 1m/s. Compute the Reynolds number. m3 Compute the friction factor, if Reynolds number in pipe flow is 1000.
Consider an oil of density p 800 kg/m3, viscosity u 0.01 Pa.s (10 times the viscosity of water), heat capacity of Cp 2 k]/(kg K) and thermal conductivity of Koll -0.15 W/(mk). This oil flows at mass flowrate of 30 kg/minute through a copper pipe of d- 2 cm inner diameter, with wall thickness of t-1 mm. At the relevant conditions, copper has thermal conductivity of ke 400 W/(m.K). The copper pipe loses heat to the surroundings of Tsurr 20°C...
Water at 15 degree Celsius , density = 999kg/cubic meter, viscosity = 0.001138 kg/ms , is flowing steadily in a 5 cm diameter horizontal pipe made of stainless steel at a rate of 0.006 m3/s . Determine the pressure drop, the head loss and the required pumping power input for flow over a 60m long section of the pipe.
PROBLEM 3 IWD * 10cm -> Aiz Viscosity 8x10 PS density 1 kg/m3 Air DJ5 ms (a) Find the dog cylinden when is 5 m/s. force on the the wind speed
2. An oil having density of 833 kg/m3 and a viscosity of 3.3 x 103 Pa.s is pumped from an open tank to a pressurized tank held at 345 k Pa gauge. The oil is pumped from an inlet at the side of the open tank through a line of commercial steel pipe having an inside diameter of 0.07792 m at the rate of 3.494 x 103 m'/s. The length of the straight pipe is 122 m and the pipe...
Water (density = 1000 kg/m3, viscosity = 1.15 x 10-3 N-s/m2) is delivered from a large reservoir upstream (Section"1") through two mortar lined steel circular pipes arranged in series to another large reservoir downstream (Section "2") as shown in Figure E4.7 The upstream pipe is 80 m long and 0.15 m in diameter, whereas the downstream pipe is 50 m long and 0.1 m in diameter. Both pipes have sharp-edged entrance and exit. Consider both major and minor losses. Determine...