Over the last two years, the Petroleum Engineering Guidebook has had five printings. And some major improvements along the way.
The original book was merely my own unedited notes, albeit carefully compiled for a decade. I gave copies of these away to friends and other engineers taking the PE Exam.
However, as new requests overwhelmed my limited printing resources (and my wife's patience) I listed it on Amazon to cover printing costs. I then slowly cleaned up the typos over 2016 and 2017 (with suggestions from other engineers; thank you, you know who you are!). The latest edition, an officially bound, paperback book, is sold, printed, and shipped directly from Amazon.
The Guidebook was always intended for industry use. Because of this, I kept practice problems separate. Upon request, however, I generated digital problems that test-takers can use alongside the Guidebook for practice. Note I provide digital format only and advise not bringing practice problems to the PE Exam itself. Why? If you waste time trying to find the "right" type of problem you will likely do yourself more harm than good. Those test-writers are smarter than that.
So the most current book (2018, 1st edition) is a $55 paperback. It's got new additions requested by 2016 & 2017 test-takers (such as hydrates, economics, probability, decision trees, bits, produced water, etc.).
Here's the thing: if you have purchased a spiral copy from me through Amazon I'll replace it with the new paperback at cost. Just mail me your old book with a self-addressed, stamped envelope and PayPal my email $3 (or put it in envelope) to offset printing costs (but email me first so I can verify you are an original purchaser & get a book ready). It's going to be a first-come, first-serve thing.
UPDATE: I'm mailing off 3 books today but I still a lot left. So even those who have plagiarized versions (there are a lot floating around), send me an email and we can arrange a swap of some kind. The new version is much better, especially for the exam.
Wednesday, May 30, 2018
Thursday, May 3, 2018
PEH Volume I Chapter 12: Crude Oil Emulsions
C1-3: Math
C4: Fluid Sampling
C5: Gas Properties
C6: Oil Correlations
C7: Thermo/Phase
C8: Phase Diagrams
C9: Asphaltene/Wax
C10: Produced Water
C11: Phase Behavior
C12: Emulsions
C13: Rock Properties
C14: Permeability
C15: Relative Permeability
C16: Economics
C17-18: Law
C4: Fluid Sampling
C5: Gas Properties
C6: Oil Correlations
C7: Thermo/Phase
C8: Phase Diagrams
C9: Asphaltene/Wax
C10: Produced Water
C11: Phase Behavior
C12: Emulsions
C13: Rock Properties
C14: Permeability
C15: Relative Permeability
C16: Economics
C17-18: Law
Emulsions are a common yet poorly-understood oilfield reality. Like hydrates, they seem to slip through the cracks and few want to claim them: do they belong to facilities, PVT, or production? I've just added yet another page to the Guidebook that deals with this complicated subject (7 PRD 13). The primary source? PEH chapter 12. See below:
Produced water:
normally “free”; if an emulsion, typically:
water droplets dispersed (as
internal phase, same surface area)…
…within oil or other (the
external/continuous phase).
May be: “water in oil” (up to 80% water cut), or “oil in
water” (>80% water cut), or more complex.
Emulsions:
found everywhere; reservoir, wellbore,
wellhead, facility, plant.
Created by:
mixing (valves, pores, etc.) + emulsifier (stabilizing agent,
such as fine solids & surfactants).
Surfactants: compounds
partly soluble in oil and water.
Water-wet particles stabilize oil-in-water
emulsions; Oil-wet particles stabilize water-in-oil emulsions.
Natural emulsions
come from the “heavy” crude fraction.
Asphaltenes change wettability of solids so they act
as emulsifiers.
Waxes crystalize if cooled below “cloud point” and
create emulsions.
Tighter emulsions mean more, smaller droplets
(more stable).
Sedimentation: settling water in an emulsion (due
to oil/water density differences).
Creaming: raising oil droplets in the water phase
(due to higher density of oil).
Emulsion treatment
(demulsify) typically means removing water & associated salts.
Demulsification
breaks emulsion to oil & water phases: 2 steps 1) flocculation, 2) coalescence.
Flocculation: aggregation/agglomeration/coagulation
of component phases.
Coalescence: droplets irreversibly
fuse (larger drops/lower surface area); high water cut enhanced.
Treatments: chemical
(common), heating (common), electrostatic field (coalescence),
settling.
Chemical demulsifiers: surface-acting
compounds that neutralize emulsifying agent stabilizing effect.
Emulsion separation time:
hours to days = “stable” or “tight”; minutes = “loose”.
Aromatic content in crude
reduces emulsification.
Stability measured with a
bottle test (estimates demulsifier phase separation time).
Mechanical emulsion-breaking: free water knockout
drums/separators/desalters/settling tanks.
Emulsion prevention:
reduce solids/chemicals/acids (make very tight emulsions)/mixing/turbulence.
Macroemulsion
& microemulsion differences because of formation and stability
differences.
Macroemulsion: drop size >0.1 micrometer and
will separate (thermodynamically unstable).
Most oilfield macro droplet
coalescence can be reduced through a stabilization mechanism.
Microemulsion: drop size <10 nanometers, separate
(thermodynamically stable).
Emulsion Separation
Index Test (ESI): quantitative
method for lab demulsifier testing (I-569).
…measure water amount separated
at 5, 10, 15, 20 min; then 20 min centrifuged.
…bottle tests have a “qualitative”
edge (due to sampling/operator/measurement error).
…uses dead crude (yet fresh
emulsion samples to minimalize error).
Calculating ESI = [(Sum
of Volume Separated with time)]/[(%BS&W)(# tests)]
Example: ESI = [0 +
4 + 12 + 19 + 25]/[(25)(5)] = 48% water
separation
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