DIMENSIONLESS REYNOLDS NUMBER AS A DIMENSION FOR FLUID MECHANICS IN RHEOLOGY
Keywords:
Newtonian Flow, Non Newtonian Flow, Bingham Flow, Laminar Flow, Turbulent Flow, Plastic Flow, Pseudo plastic Flow, Dilatant Flow, Thixotropic Flow, Transitional FlowAbstract
ABSTRACT
Reynolds number, in fluid mechanics, a criterion of whether fluid (liquid or gas) flow is absolutely steady (streamlined, or laminar) or on the average steady with small unsteady fluctuations (turbulent). Whenever the Reynolds number is less than about 2,000, flow in a pipe is generally laminar, whereas, at values greater than 2,000, flow is usually turbulent. Actually, the transition between laminar and turbulent flow occurs not at a specific value of the Reynolds number but in a range usually beginning between 1,000 to 2,000 and extending upward to between 3,000 and 5,000.
In 1883 Osborne Reynolds, a British engineer and physicist, demonstrated that the transition from laminar to turbulent flow in a pipe depends upon the value of a mathematical quantity equal to the average velocity of flow times the diameter of the tube times the mass density of the fluid divided by its absolute viscosity. This mathematical quantity, a pure number without dimensions, became known as the Reynolds number and was subsequently applied to other types of flow that are completely enclosed or that involve a moving object completely immersed in a fluid.
Keywords: Newtonian Flow, Non Newtonian Flow, Bingham Flow, Laminar Flow, Turbulent Flow, Plastic Flow, Pseudo plastic Flow, Dilatant Flow, Thixotropic Flow, Transitional Flow
