How can I solve these tasks? Water (Pwater = 1000 kg/m³) is supplied through a softdhose with diameter D =75 mm, to a fire-fighting gunDcarriage, with diameter d = 38 mm. Determine the reactionforce of the outgoing flow in the carriage, if the gagepressure in the hose is phose (aage) = 4. 105 Pa and the waterflowrate is Q =1.102 m³/s . Problem 10The pressure drop, due to the head and minor losses, between the two ends ofa horizontal pipeline is AProtal loss = 27.6 kPa. The length of the pipeline is / = 100m, the diameter is d = 0.1 m and the wall roughness coefficient is k = 0.5 mm. Thesum of the minor loss coefficients in the pipeline is = 5. Determine the flowrateQ, if this pipeline is used for transportation of water (Pwater = 1000 kg/m³, vwater1.004 .10-6 m?/s).%D%3D

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= 1000 kg/m³) is supplied through a soft 75 mm, to a fire-fighting gun carriage, with diameter d = 38 mm. Determine the reaction force of the outgoing flow in the carriage, if the gage = 4. 105 Pa and the water Water (Pwater hose with diameter D = pressure in the hose is Phose (gage) flowrate is Q = 1.102 m³/s.

= 1000 kg/m³) is supplied through a soft 75 mm, to a fire-fighting gun carriage, with diameter d = 38 mm. Determine the reaction force of the outgoing flow in the carriage, if the gage = 4. 105 Pa and the water Water (Pwater hose with diameter D = pressure in the hose is Phose (gage) flowrate is Q = 1.102 m³/s.

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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