Consider a 50-cm-diameter sewer (n = 0.013) on a slope of 0.003 m/m. Calculate the flow...

A rectangular concrete channel with n=0.013 is to be constructed on 0.5% slope: 1. Design for...

A rectangular concrete channel with n=0.013 is to be constructed on 0.5% slope: 1. Design for a flow rate of Q=18 m^3/s. 2. A 30 cm high, 5 m long broad crested weir is placed in the channel. Calculate the depth upstream y1 and downstream y2 from the weir then get the head loss due to the hydraulic jump

A 10-m wide, rectangular, concrete-lined canal (n=0.013) has a bottom slope of 0.01 and a constant-level...

A 10-m wide, rectangular, concrete-lined canal (n=0.013) has a bottom slope of 0.01 and a constant-level lake at the upstream end. The steep canal carries a flow of is 250 m3/s and the critical and normal depths are 4m and 2.37m, respectively. The water level in the lake is 6.0 m above the bottom of the canal at the entrance. If the entrance losses are negligible, using Direct Step Method determine; i. The flow depth 812 m downstream of the...

A circular storm water sewer 1.5 m in diameter and effective roughness size 0.6 mm is...

A circular storm water sewer 1.5 m in diameter and effective roughness size 0.6 mm is laid to a slope of 1:500. Determine the maximum discharge which the sewer will convey under uniform open channel conditions. If a steady inflow from the surface runoff exceeds the maximum open channel capacity by 20%, show that the sewer will become pressurized and calculate the hydraulic gradient necessary to convey the new flow. (ans. 3.6 m3/s and 0.00324) without using the mannings formula...

A circular storm water sewer 1.5 m in diameter and effective roughness size 0.6 mm is...

A circular storm water sewer 1.5 m in diameter and effective roughness size 0.6 mm is laid to a slope of 1:500. Determine the maximum discharge which the sewer will convey under uniform open channel conditions. If a steady inflow from surface runoff exceeds the maximum open channel capacity by 20%, show that the sewer will become pressurised (surcharged) and calculate the hydraulic gradient necessary to convey the new flow.

Consider the fully developed flow of glycerin at 40C Trough a 70m long, 4 cm diameter,...

Consider the fully developed flow of glycerin at 40C Trough a 70m long, 4 cm diameter, horizontal, circular pipe. if the flow velocity at the centerline is measured to be 6 m/s, determinate the velocity profile and the pressure difference across this 70m long section of the pipe, and the useful pumping power required to maintain this flow.

The discharge through a rectangular channel 4.4 m wide is 16 m3/s. The Manning’s coefficient n...

The discharge through a rectangular channel 4.4 m wide is 16 m3/s. The Manning’s coefficient n is 0.003. Determine the normal depth when the slope is 0.008. Check whether the flow is sub or supercritical. If the normal depth is to be kept at 2 m, determine the slope.

Consider the flow of oil at 10?C in a 40-cm diameter pipeline at an average velocity...

Consider the flow of oil at 10?C in a 40-cm diameter pipeline at an average velocity of 0.5 m/s. A 1500-m long section of the pipeline passes through icy waters of a lake at 0?C. Disregarding the thermal resistance of the pipe material, determine (a) the temperature of the oil when the pipe leaves the lake (b) the rate of heat transfer from the oil and (c) the pressure losses in the pipe. Assume the flow is hydro-dynamically fully developed.

A pipe with diameter 30 cm carries oil of sp.gr. 0.95 at a velocity of 4...

A pipe with diameter 30 cm carries oil of sp.gr. 0.95 at a velocity of 4 m/s .at another section the diameter change to 20 cm . Find the velocity at this section and also find the mass flow rate of oil . my question kinematics of flow

Exercise 4. A rectangular xsect canal of 10 m wıdth, carries a uniform flow at a...

Exercise 4. A rectangular xsect canal of 10 m wıdth, carries a uniform flow at a rate of 30 m3/s with 1,2 m depth. A drainage pipe of 50 cm diameter is constructed at the bottom of the canal. Investigate the new flow conditions and draw the flow surface variation at the pipe xsect vicinity.

1) Determine the critical depth, critical slope and Froude Number at section y=0.4 m in a...

1) Determine the critical depth, critical slope and Froude Number at section y=0.4 m in a 1 m wide rectangular channel carrying 1.5 m3 /s. n=0.014. 2) Design a circular channel to convey Q=4 m3 /sec, in order to have maximum velocity. n=0.014, S0=0.008.. 3) Design a circular channel to convey flow rate Q=3 m3/sec, in order to have the flow depth y=1.5, n =0.014, bed slope 0.0006.