When a well is produced the fluid comes
to the surface as an emulsion of oil,
water, gas, and solids. Emulsions in the
oil and gas industry are either
classified as water-in-oil or oil-in-water, depending on the ratio of the
volumes of liquids. Gas brought to the
surface is usually wet gas composed of
dry, natural gas like methane, mixed with
liquid natural gases like ethane and butane.
All of these components are
separated using multiple principles of
separation to achieve the desired end
products that are considered valuable.
In this video we'll explain six separation
principles used for emulsion in the oil and gas industry.
The first principle we'll discuss is heat.
When separating liquids from each other, heating to certain temperatures enhances separation.
When the temperature of an oil and water
emulsion is increased, the viscosity of oil is decreased.
This lower viscosity allows the gas and water molecules to be more easily released.
Heating oil emulsions also increases density between oil and water.
A heater treater is an example of a vessel which uses the
principle of temperature change to aid
in separation. For more on how a heater
treater works, check out our training
level-one series.
Our second principle is gravity separation.
The elements in the well stream, such as oil and water, have different gravities.
The density differences allow water to separate by gravity.
With enough time in a non-turbulent state, the differing specific
gravities will naturally separate. To
picture this, think of the emulsion as
Italian salad dressing. If you let the
dressing set the ingredients will
separate according to their different
specific gravities – the olive oil will
float on top because it is lighter than
the vinegar and the solids and other
ingredients will fall to the bottom
because they are the heaviest.
The next principle directly relates to gravity separation and it's called retention time.
Retention time is the amount of time the fluid stays in a steady or non-agitated state inside a separator.
Longer retention time means more separation.
A larger diameter or taller vessel will
increase the retention time and allow
more water to settle out by gravity.
In this visual of a sample of emulsion from a free water knockout
you can see three layers – oil water and solid – which separated over time.
Our fourth principle of separation is agitation.
A production fluid is agitated when it hits the diverter plate at the inlet of a vessel.
The sudden impact on the plate causes a
rapid change in the direction and
velocity which helps break the surface
tension of the liquids and start the
separation process. There are many styles of diverter plates and separators and
the choice will be made by the
attributes and volume of the well stream.
Coalescing is related to the agitation
process. During coalescence, water
droplets come together to form larger
drops. In vane type mist eliminators,
droplets are removed from the vapor
stream through inertial impaction.
The wet gas is forced to change direction
causing mists droplets to strike the
vanes and coalesce with other droplets
eventually falling.
This inertial impaction also occurs in mesh type mist eliminators.
Gas must flow around each strand of mesh and when miss droplets
strike the filaments they adhere and
coalesce to form droplets large enough to fall.
Sub-micron droplets are forced
to zigzag through the close-packed
fibers with Brownian motion and will
eventually strike, adhere, coalesce and drain.
Our final principle of separation is the use of chemical demulsification.
The chemicals move to the oil and water interface,
weakening the surface tension
and enhancing coalescence.
Knowing which chemicals to use and the correct dosage can be complex but the desired effect
will minimize the amount of heat or
retention time required for separation.
Still have questions about separation
drop them in the comments below or
contact an expert at your local Kimray
store or authorized distributor.
