Design a trapezoidal concrete lined channel (n = 0.013) to convey 3m3 /sec on a slope...

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

1. A trapezoidal channel carrying 11.5 m3/s clear water is built with concrete (no erodible) channel...

1. A trapezoidal channel carrying 11.5 m3/s clear water is built with concrete (no erodible) channel having a slope of 0.0016 and n= 0.025. Proportion the section dimensions. Use best hydraulic section approach

Design a gravel riprap-lined trapezoidal channel to carry 11.33 m3/s by considering the best hydraulic section...

Design a gravel riprap-lined trapezoidal channel to carry 11.33 m3/s by considering the best hydraulic section with a slope S0 = 0.0016. Solve the problem using the tractive force method from the textbook (Chapter 15.3.2). (Note: you need to find the gravel size so that the design criteria are satisfied).

A trapezoidal channel (Manning, n = 0.012) is to be designed to carry a discharge of...

A trapezoidal channel (Manning, n = 0.012) is to be designed to carry a discharge of 14 m3/s at a slope of 0.003. The sides slope is to be fixed at 1V: 1.5H. Determine the dimensions of the channel based on the best hydraulic section criteria. Check the adequacy of the design in term of its Froude number.

Design a rectangular riprap channel to convey 30 cfs with a velocity of 2.5 ft/sec. Use...

Design a rectangular riprap channel to convey 30 cfs with a velocity of 2.5 ft/sec. Use the high end of the n-value for riprap. The slope is 0.5 percent. Solve analytically, i.e., set up equations for properties (area, wetted perimeter, and hydraulic radius) and solve for the unknowns. Then check. No credit if analytic solution is not included

Design a rectangular riprap channel to convey 30 cfs with a velocity of 2.5 ft/sec. Use...

Design a rectangular riprap channel to convey 30 cfs with a velocity of 2.5 ft/sec. Use the high end of the n-value for riprap. The slope is 0.5 percent. Solve analytically, i.e., set up equations for properties (area, wetted perimeter, and hydraulic radius) and solve for the unknowns. Then check using a spreadsheet. No credit if analytic solution is not included!

A trapezoidal channel is 6 m wide and has a side slope of 0.5 horizontal: 1...

A trapezoidal channel is 6 m wide and has a side slope of 0.5 horizontal: 1 vertical. If the bed slope of the channel is 0.0004 and Manning’s n = 0.02, find the discharge which can make the channel a hydraulically efficient channel section.

Consider the California aqueduct, which is a concrete trapezoidal channel with a bottom width of 40...

Consider the California aqueduct, which is a concrete trapezoidal channel with a bottom width of 40 ft, a longitudinal slope of 0.004% and 1.5H:1V sideslopes (z = 1.5). Assume n = 0.013. The design discharge is 6400 mgd. (use 9900 cfs) The depth of water is 29 ft at point A. The depth of water is 30 ft at point B. (a) What is the normal depth? b) Determine the critical depth. (c) What type of profile exists in the...

A concrete, trapezoidal channel with a 5-m bottom width and side slopes of 1:1 (H:V) discharges...

A concrete, trapezoidal channel with a 5-m bottom width and side slopes of 1:1 (H:V) discharges 35 m3/sec. The bottom slope of the channel is 0.004. A dam is placed across the channel and raises the water level to a depth of 3.4 m. determine the channel and flow classification (e.g., M-2, S-1) upstream of the dam and explain your supporting logic. then compute the water surface profile at 50-m intervals until you reach the hydraulic jump. Use a spreadsheet...

A hydraulic jump is formed in a trapezoidal channel of 2.0-m bed width, 1:1 side slope,...

A hydraulic jump is formed in a trapezoidal channel of 2.0-m bed width, 1:1 side slope, and carrying a discharge of 6.0 m3/s. The initial and final depths of the jump are 0.5m and 2.0m, respectively. Concrete blocks are placed to stabilize the jump. Cf = 0.6. Construct the M-y diagram for the channel section. Find the critical depth.