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Example: Exercise 5.9.4 (Pump)

Example: Exercise 5.9.4 (Pump). Pump. Flow. Oil (S=0.82). Want: Rate at which energy is delivered to oil by pump. Need to find h p associated with the pump:. Example: Exercise 5.9.4 (Pump). Rate of transfer of energy =. Example: Exercise 5.9.4 (Pump).

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Example: Exercise 5.9.4 (Pump)

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  1. Example: Exercise 5.9.4 (Pump) Pump Flow Oil (S=0.82) Want: Rate at which energy is delivered to oil by pump Need to find hp associated with the pump:

  2. Example: Exercise 5.9.4 (Pump) Rate of transfer of energy =

  3. Example: Exercise 5.9.4 (Pump) • Pumps (and also turbines) are characterized by their efficiency. • Say, in exercise 5.9.4 the pump is 90% efficient and we require • 6.83 kW of output, then input = 6.83 kW / 0.9 = 7.59 kW • Pumps (and also turbines) are characterized by their efficiency. Efficiency =

  4. General Energy Equation for Steady Flow of Any Fluid First Law of Thermodynamics: For steady flow, external work done on any system plus the thermal energy transferred into or out of the system is equal to the change of energy of the system (I) Using the first law of thermodynamics, (II) taking into account non-uniform velocity at a cross-section of flow region, and (III) assuming flow goes from section 1 to section 2, we can derive the following:

  5. General Energy Equation for Steady Flow of Any Fluid • is a correction factor accounting for non-uniform velocity in cross-section • If velocity is uniform in cross-section, then • This general equation also takes into account changes in density (via ) • energy changes due to machines (via ) and due to heat transfer to • or from outside the fluid (via ) • It also accounts for the conversions of other forms of fluid energy into internal • heat ( )

  6. General Energy Equation for Steady Flow of Any Fluid • On a unit weight basis, the change in internal energy is equal to the heat • added to or removed from the fluid plus the heat generated by fluid friction: • The head loss due to friction is equal to the internal heat gain minus any • heat added from external sources, per unit weight of fluid • Energy loss due to friction gets converted to internal energy (proportional to • temperature)

  7. Example: Exercise 5.3.5 (Friction Head Loss) S of liquid in pipe = 0.85 A Diameter at A = Diameter at B, thus by continuity B Want: Pipe friction head loss and direction of flow Assume flow goes fom A to B:

  8. Example: Exercise 5.3.5 (Friction Head Loss) S of liquid in pipe = 0.85 A Diameter at A = Diameter at B, thus by continuity B Thus flow goes from B to A and

  9. Example: Exercise 5.3.5 (Friction Head Loss) S of liquid in pipe = 0.85 A Diameter at A = Diameter at B, thus by continuity B Thus flow goes from B to A and Let . If flow goes from B to A, and

  10. Role of pressure difference (pressure gradient) A B Thus flow will go from B (high pressure) to A (low pressure), only if Otherwise flow will from A (low pressure) to B (high pressure) In general, the pressure force (resulting from a pressure difference) tends to move a fluid from a high pressure region towards a low pressure region For a flow to actually go from a high pressure region towards a low pressure region, the pressure force must be higher than other forces that could be trying to move fluid in opposite direction (e.g. gravitational force in exercise 5.3.5)

  11. Energy Grade Line (EGL) and Hydraulic Grade Line (HGL) Graphical interpretations of the energy along a pipeline may be obtained through the EGL and HGL: EGL and HGL may be obtained via a pitot tube and a piezometer tube, respectively

  12. Energy Grade Line (EGL) and Hydraulic Grade Line (HGL) • head loss, say, • due to friction EGL=HGL if V=0 EGL HGL piezometer tube pitot tube Datum

  13. Energy Grade Line (EGL) and Hydraulic Grade Line (HGL) EGL and HGL EGL Large V2/2g because smaller pipe here HGL Steeper EGL and HGL because greater hL per length of pipe Head loss at submerged discharge EGL and HGL

  14. Energy Grade Line (EGL) and Hydraulic Grade Line (HGL) Positive Negative EGL and HGL Positive EGL HGL If then and cavitation may be possible

  15. Energy Grade Line (EGL) and Hydraulic Grade Line (HGL) Helpful hints when drawing HGL and EGL: 1. EGL = HGL + V2/2g, EGL = HGL for V=0 2. If p=0, then HGL=z 3. A change in pipe diameter leads to a change in V (V2/2g) due to continuity and thus a change in distance between HGL and EGL 4. A change in head loss (hL) leads to a change in slope of EGL and HGL 5. If then and cavitation may be possible

  16. Helpful hints when drawing HGL and EGL (cont.): 6. A sudden head loss due to a turbine leads to a sudden drop in EGL and HGL 7. A sudden head gain due to a pump leads to a sudden rise in EGL and HGL 8. A sudden head loss due to a submerged discharge leads to a sudden rise in EGL

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