Problem 4: Consider again Problem 3 with a constant pressure gradient (Fig. 5) in the x-direction (dp/dx) 
and: 

a) Simplify the governing equations (continuity and momentum) for the flow;
b) Apply the boundary conditions and determine the velocity profile;
c) Develop expressions for the flow rate and mean velocity from the velocity profile.

 

ignore anything that referenes drilling engineering (i.e. part D). I realize there isn't a drilling engineering expert but that isn't the point of the question either.. Problem 3 is attached for reference.

Transcribed Image Text:

Problem 3: Consider incompressible Newtonian fluid flow between parallel plates (Fig. 4) that are horizontal and a distance h apart. The plates can be considered as very wide and very long so that the flow is essentially axial; hence, u ‡ 0 but v = w = 0 and a/az-0. B represents the plate width. The flow is fully developed laminar and steady. a) Simplify the governing equations (continuity and momentum) for this flow; B Fixed Fig. 4 u(y) b) Apply the boundary conditions and determine the velocity profile; c) Develop expressions for the flow rate and mean velocity from the velocity profile. h

Transcribed Image Text:

Problem 4: Consider again Problem 3 with a constant pressure gradient (Fig. 5) in the x-direction (dp/dx) and: a) Simplify the governing equations (continuity and momentum) for the flow; b) Apply the boundary conditions and determine the velocity profile; c) Develop expressions for the flow rate and mean velocity from the velocity profile. d) Discuss how these formulas can be used in drilling applications (Applied Drilling Engineering, pages 165-166) y h Fig. 5 Flow between parallel plates with pressure gradient