By using the yield line theory, determine the ultimate resisting moment per linear meter (m) for an isotropic reinforced concrete two-way slab to sustain a concentrated factored load of P kN applied as shown in figure. Use equilibrium method in solution Column 2.0 P 8.0 m m m XXXX

By using the yield line theory, determine the ultimate resisting moment (m) for an isotropic reinforced concrete two-way slab shown in figure under a uniform load (q). Use equilibrium method in solution m m column 20 m 20 m

In Tikrit city, environmental engineers are monitoring the diffusion of CO2 in the air as part of a pollution control study. The air-carbon dioxide mixture is at 295 K and 202.6 kPa, and the concentration of CO2 at two planes, 3 mm apart, is 25 vol.% at the first plane and 15 vol.% at the second plane. The diffusivity of CO2 in air under these conditions is 8.2 × 106 m²/s. The study aims to calculate the rate of CO2 transfer across these two planes in two different scenarios: 1. What is the main engineering issue being addressed in this scenario? 2. Calculate the concentration of CO2 at the two planes in mol/m³ and determine the rate of transfer of CO2 using the diffusivity of CO2 in air. 3. With an engineering solution approach to solve the issue, calculate the rate of transfer of CO2 across the two planes assuming two scenarios: equimolecular counter diffusion and diffusion through a stagnant air layer. 4. Determine if there is a significant difference between the results of…

Introduction: Orifice and Free Flow Jet in Applied Fluid Mechanics' I need to introduction only for answer

The circular slab of radius 2 m supported by three columns, as shown in figure, is to be isotropically reinforced. Find the ultimate resisting moment per linear meter (m) required just to sustain a uniformly distributed load (q) equals 16 kN/m². Use equilibrium method in solution m Column m

Vehicles begin to arrive at a parking lot at 7:45 A.M. at a constant rate of 4 veh/min and continue to arrive at that rate throughout the day. The parking lot opens at 8:00 A.M. and vehicles are processed at a constant rate of one vehicle every 10 seconds. Assuming D/D/1 queuing, what is the longest queue, the queue at 8:15 A.M., and the average delay per vehicle from 7:45 A.M. until the queue clears?

1. Gunakan teor luasi momen untuk menentukan putaran sudut (slope) di B. Gunakan E = 200 GPa dan I-70 x 100 mm². m 8 kN·m B 2. Gunakan teori luas momen dan tentukan putaran sudut (slope) di A dan perpindahan di C. Gunakan E = 200 GPa dan I = 70 x 100 mm². 4 kN 4 kN -2 m 2 m- B 4 m 4 m

Consider the conditions in Practice Problem 5.2. How short would the driver reaction times of oncoming vehicles have to be for the probability of an accident to equal 0.20?

Part 4: Problem-Solving. Solve the following problems. Show all calculations. 1. A Standard Penetration Test (SPT) was conducted at a site, and the following blow counts were recorded: Depth: 2 m, Blow count (N): 10 D D Depth: 4 m, Blow count (N): 15 Depth: 6 m, Blow count (N): 20 The energy ratio is 60%, and the overburden correction factor CN is 1.1. Calculate the corrected N-values for each depth. 2. A soil sample was collected from a depth of 3 m using a Shelby tube. The sample had a volume of 0.01 m³ and a mass of 18 kg. If the water content is 12%, calculate the (a) bulk density, (b) dry density, and (c) void ratio of the soil. Assume the specific gravity of soil solids (Gs) is 2.65. 3. A Cone Penetration Test (CPT) was conducted at a site, and the following data was obtained: Depth: 2 m, Cone resistance (qc): 5 MPa Depth: 4 m, Cone resistance (qc): 8 MPa Depth: 6 m, Cone resistance (qc): 12 MPa Estimate the soil type at each depth using typical qc correlations.