6 x 2/ Given in the design of the followingmovable grid system: field dimensions(360m x 1080m), soil mixture alluvial,effective depth of root zone (80 cm), Germanconsumption (8mm / day), sprinklers(Jism and 9m), average Wind speed (2m /sec), water holding capacity (1.7mm /cm), moisture depletion rate (50%), baseinfiltration rate (10.2mm / hr), note that theirrigation efficiency is (659). The main pipepasses outside the field. The spray tubeis made of Aluminum material dischargecoefficient (0.967 = c) required:. 1. Netirrigation depth 2- Irrigation interval 3- Totalirrigation depth 4- Irrigation rate b) Numberof spray tubes needed for the field c)Sprinkler drainage, spray diameter, pressurecharge rate d Diameter of spray pop in cases:6 1- Spray pop Hesto 2 The spray pop hasa downward slope of (19). 3- The spray pophas a slope of (19). The pressure charge atthe entrance and end of the spray tube for thethree cases in d%3D

Given that field dimensions are 1080 m x 360 m Depth of the root zone is 80cm Water consumption =…

Answered: 6 x 2/ Given in the design of the…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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The data presented in the figure shows a generic 2.5MW wind turbine power curve and a wind speed data at hub height. 2500 0.25 2000 0.20 1500 0.15 1000 0.10 50 0.05 0.00 o 2 4 6 8 10 12 14 16 18 20 Wind speed (m/s) wWind speed frequency Power generated by wind turbine Estimate the Annual Energy Production that this wind turbine is able to generate. Power (MW) ksuanbay paads puM
Please solve this using the second image to reference which dimensions to find to make it have the design factor and yield. And anything else necessary listed.
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1. Consider a two-dimensional flow which varies in time and is defined by the velocity field, u = 1 and v = 2yt. a) Is the flow field incompressible at all times? b) Compute the convective derivative of each velocity component: Du/Dt and Dv/Dt. c) By considering the velocity gradients, determine whether the fluid elements experience any deformation. What type(s) of deformation do they experience? d) Do the fluid elements experience angular rotation? Thus, state whether the flow field is rotational or irrotational. e) Given that the density of the fluid does not vary spatially and changes only with time, what differential equation for the density, p(t), must be satisfied for this scenario to represent a physical, compressible flow field? f) At time t = 0, the density everywhere is p = Po. Determine how the density changes with time, given the situation does represent a physical, compressible flow field.
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If the velocity varies linearty with distance through this fluid nozzie (vertical nozzle), where the specific gravity of the fluid is S-0.46, what will be the pressure gradient, halfway through the nozzle? Assume steady and inviscid flow 2 m/s 50 cm 6 mis Select one a. 38465.20 O b. -57697.80 O e. 19232.60 O d. 9616.30 e. 76930.40
Q3. (a) Explain the importance of GIS is environmental risk assessment (b) Describe the GIS requirements for environmental risk assessment (c) Use the input data in Figure Q3 to identify erosion hotspot pixels in the study area (d) Calculate the assessment accuracy based on the Nash-Sutcliff coefficient of efficiency Cells (15m by 15m) Cell с 2 Input data for soil erosion modelling Rainfall (mm) Sand (%) Silt (%) Drainage Slope (%) BRed BIRed Conservation Actual Erosion (t/h/y) 121 20 45 High 3 0.231 0.314 Fallow (0.7) 0.09 211 11 44 High 12 0.012 0.121 None (1) 0.12 DE 121 38 55 Rapid 8.1 0.181 0.712 Grass strip (0.1) 0.15 238 24 18 Slow 4.5. 0.311 0.671 Contour (0.3) 0.078 102 17 29 Moderate 7.5 0.27 0.413 Contour (0.3) 0.62 89 44 27 Rapid 5.5 0.118 0.312 None (1) 0.31 Study area G 103 23 33 Slow 6 0.071 0.232 Fallow (0.7) 0.55 H 90 55 15 Rapid 2.1. 0.082 0.32 None (1) 1.28 130 18 32 Moderate 13. 0.11 0.44 Grass strip (0.1) 1.5 ⚫ Rainfall erosivity; R = 0.715*P-6.12 (P mean annual…

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