6) Shear stresses in a hydrostatic domain are always equal to zero. 7) In a hydrostatic domain, imagine two different fluids, one with higher viscosity and the other one is with lower viscosity. The spęcific weight of these fluids is the same. When these two fluids (with the same volumé) placed into the identical tanks in terms'of size, the fluid with higher viscosity create higher pressure at the bottom of the tank. 8) The difference between absolute pressure and relative pressure is equal to atmospheric pressure. 9) According to Pascal's law, the pressure is the same in all points of water-filled vessels. 10) There is a linear relationship between pressure and depth in a hydrostatic environment for Bingham fluid (non-Newtonian Fluid).

6) Shear stresses in a hydrostatic domain are always equal to zero. 7) In a hydrostatic domain, imagine two different fluids, one with higher viscosity and the other one is with lower viscosity. The spęcific weight of these fluids is the same. When these two fluids (with the same volumé) placed into the identical tanks in terms'of size, the fluid with higher viscosity create higher pressure at the bottom of the tank. 8) The difference between absolute pressure and relative pressure is equal to atmospheric pressure. 9) According to Pascal's law, the pressure is the same in all points of water-filled vessels. 10) There is a linear relationship between pressure and depth in a hydrostatic environment for Bingham fluid (non-Newtonian Fluid).

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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