P3.138*: Viscosity in a Capillary Tube - PowerPoint PPT Presentation
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P3.138*: Viscosity in a Capillary Tube
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P3.138*: Viscosity in a Capillary Tube Solved By: Rebecca Currier Patrick Thomas Andrew Quinn Nicole Hataway The Problem Find: a) If d, L, H, Q , T, and are known ... – PowerPoint PPT presentation
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Title: P3.138*: Viscosity in a Capillary Tube
1
P3.138 Viscosity in a Capillary Tube
- Solved By Rebecca Currier
- Patrick Thomas
- Andrew Quinn
- Nicole Hataway
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The Problem
- A viscometer
- Consists of a tank and a long vertical capillary
tube - The laminar head loss is given by
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Find
- a) If d, L, H, Q , T, and ? are known, write an
expression for the viscosity. - b) Calculate the viscosity T20oC,
- ?681 kg/m3
- d0.041 in (1.0414mm)
-
Q0.310mL/s - L36.1 in (0.91694m)
- H0.154m.
- c) Compare the experimental result with the
published value of viscosity at this temperature,
and report a percent error. - d) Compute the percentage error in the
calculation of viscosity that would occur if a
student forgot to include the kinetic energy flux
correction factor in part (b). Explain the
importance of the kinetic energy flux correction
factor in a problem such as this.
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Assumptions
- Neglect Entrance Losses
- Laminar Flow
- Standard Temperature and Pressure Conditions
- Steady
- Incompressible
- Viscous
- Liquid (We chose Gasoline, experimental ?681
kg/m3)
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The Setup
- Start with the incompressible steady flow energy
equation (3.71) - Neglect pressure head because both the inlet and
the outlet are open to the atmosphere - Height at outlet 0
- Neglect incoming fluid velocity
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Part A
- Plug in equation for friction head, rearrange for
viscosity
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Part B
- Plug values into equation from Part A
- T20oC, ?681 kg/m3, d0.041 in (1.0414mm),
Q0.310mL/s,
L36.1 in (0.91694m), H0.154m. - ANSWER
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Part C
- Actual value of viscosity is 2.92e-4 kg/(ms) per
Table A.3 - Use percent error formula to determine how far
off calculated value is from gasolines actual
viscosity
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Part D
- Recalculate part A, but eliminate the friction
factor alpha (2) - New error is
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Discussion
- Several different variables affect viscosity
- These factors are dependent on each other-
changing the fluid density did not yield an
equally changed viscosity
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Relation to Biofluids
- Scenario is analogous to bladder/urethra setup
- Equation could be used to mathematically model
urine flow in catheterized patient - Entrance effects would need to be considered in
the bladder model, because the urethra is much
shorter than the capillary tube in this problem
