Concept explainers
Draw the flow net and calculate the seepage loss per meter length of the sheet pile.
Answer to Problem 8.1P
The seepage loss per meter length of the sheet pile is
Explanation of Solution
Given information:
The hydraulic conductivity of the permeable soil layer k is
The height of the water level
The height of the water level
The depth of permeable layer up to the end of sheet pile D is 3 m.
The depth of permeable layer
Calculation:
Draw the free body diagram of the flow net for the given values as in Figure (1).
Refer Figure 1.
Determine the head difference between the upstream and downstream using the relation.
Substitute 6 m for
Determine the seepage loss per meter length of the sheet pile using the relation.
Here,
Substitute
Therefore, the seepage loss per meter length of the sheet pile is
Want to see more full solutions like this?
Chapter 8 Solutions
Bundle: Principles Of Geotechnical Engineering, Loose-leaf Version, 9th + Mindtap Engineering, 1 Term (6 Months) Printed Access Card
- 7. A rectangular, unfinished concrete channel of 38-ft width is laid on a slope of 8 ft/mi. Determine the flow depth and Froude number of the flow if the flowrate is 400 ft³/s.arrow_forward***Please MAKE SURE to include all parts that I have shown in the 8 steps here and follow them but also show work for the entire problem. Those are all correct I just need the entire worked out problem with all of the work.arrow_forward***When answering the question MAKE SURE to use ALL of these steps and include them in the answer and don't answer the question in a different manner that is different than what is provided here as what is provided is correct (please include the work as well thanks I will like the answer): 1.correct equation: (ΔP / (ρg)) + ΔZ = f * (L / D) * (v^2 / 2g) + (v^2 / 2g) * ΣK_L 2.v = Q / A = 9.17 ft/s 3. Reynolds number: Re = (v * L) / ν = (v * L) / (ρ * μ) = 63,154 4.The pipe is smooth so: ε_d = 0 5.Friction factor from the Moody diagram: f = 0.020 6.Pressure difference: ΔP = P₁ - P₂ = P₁ - 8640 lb_f 7.Head loss due to elevation difference: ΔZ = Z₁ - Z₂ = -10 ft 8.Summation of pipe fittings and losses: ΣK_L = 0.2 + 7 + 2(1.5) + 0.05 = 10.25 9.values to plug in Length of the pipe: L = 20 ft Diameter of the pipe: D = 1/12 ft Fluid density: ρ = 1.94 slugs/ft³ Gravitational acceleration: g = 32.2 ft/s²arrow_forward
- 5. A uniform flow of 110,000 ft³/s is measured in a natural channel that is approximately rectangular in shape with a 2650-ft width and 17.5 ft depth. The water-surface elevation drops 0.37 ft per mile. Based on the computed Manning coefficient, n, characterize the type of natural channel observed. Also compute the Froude number and determine whether the flow is subcritical or supercritical.arrow_forwardFor the gymnasium floor plan shown, determine the dead loads and live loads acting on beam BF and girder AD.arrow_forwardThe building elevation section and the floor plans shown below. Assume a live load of 60 psf on all three floors. Calculate the axial forces by the live load in column C2 in the third and first stories. Consider live load reduction if permitted by ASCE.arrow_forward
- Q1: The part in adjacent figure has 2mm thickness is to produce in blanking process from aluminum sheet has shear strength 1. Sketch the required blanking 2. Main cutting force. 3. equal to 400 MPa. Determine: die. Sequence of shearing operations. اكد من Dimensions (mm)arrow_forward2: A (4m*8m) rectangular flexible foundation is placed above the ground surface for two layers of clay, for each layer 12m thick, The modulus of Elasticity (Eu) of the upper layer is 15 MN/m² and that of the lower is 25 MN/m². The Poisson ratio is (M = 0.35 35) for the two layers and the Column load is 90 KN. Determine the immediate settlement at the Corner of the foundation using Elastic theory method?arrow_forward11: A Square foundation is required to Carry a total load of 660 KN in cohesionless soil. The water table locates at the base of foundation. Determine the width of the foundation? (Use Terzaghi equation). Note: Jd=18 kN/m² 3 Depth of foundation = 1.2 m Factor of Safety = 3 0° = 25 ४. 8 sat ర 3 = 20 KN/m³ 3 Ow = 10 kN/m² Assume the allowable bearing Capacity is equal to the actual bearing Capacity (I actual).arrow_forward
- Fundamentals of Geotechnical Engineering (MindTap...Civil EngineeringISBN:9781305635180Author:Braja M. Das, Nagaratnam SivakuganPublisher:Cengage LearningPrinciples of Geotechnical Engineering (MindTap C...Civil EngineeringISBN:9781305970939Author:Braja M. Das, Khaled SobhanPublisher:Cengage Learning