Oil & Gas Technologies CLO 1 PDF

Summary

This document provides an overview of oil and gas technologies, covering topics like the chemistry of hydrocarbon reserves, origin, migration, and accumulation processes. It also includes information regarding refinery products, energy sources, and properties of reservoir hydrocarbons, along with discussions on different types of oil and gas traps, and exploration methods and tools.

Full Transcript

Oil & Gas Technologies

CLO 1
Topics to be covered
Part 1:
Chemistry of hydrocarbon reserves
Origin – How do oil and gas are formed?
Migration and accumulation processes of oil and gas
Part 2:
Chemical composition and different hydrocarbons of oil and gas.
Main reservoir hydrocarbons
Part 3:
Discuss the main properties of reservoir hydrocarbons.
Properties of the minerals and rocks containing the reservoir.
Part 4:
Identify the different reservoir rocks including sandstone, carbonate,
limestone etc.
Discuss sedimentary rocks characteristics.
Part 6:
Describe the different types of oil and gas traps.
 What Do You Know About
Crude petroleum (origin, quality, composition, price,…) ?
Refineries (what processes)?
Refinery products / by products?
Refineries in UAE?

The global economy receives almost 80% of its energy
subsidies from non-renewable fossil sources: crude oil,
gas and coal.

4
 What is Energy Source?
By definition, " energy sources" must produce more energy than
they consume, otherwise they are called "sinks".
Crude oil and gas are the most important form
of energy we use, making up about 63%
of the world energy supply. Different Energy
Sources
No other energy source equals oil and
gas’s intrinsic qualities of extractability,
transportability, versatility and cost.

5
 Extensive Versus Intensive Properties

Intensive/Intrinsic properties are bulk
Boiling Point
properties, which means they do not
depend on the amount of matter that is Density
present. These characteristics do not Color
depend on the amount of sample, nor Melting Point
do they change according to conditions. Hardness
Ductility
An extensive/Extrinsic property is a Volume
property of matter that changes as the specific volume
amount of matter changes. Like other
Weight
physical properties, an extensive
property may be observed and Energy
measured without any chemical change
Chemistry
Oil and gas are made of a mixture of different hydrocarbons.
A hydrocarbon is a large organic molecule made up of hydrogen
atoms attached to a backbone of carbon.

Alkanes – They are referred to as saturated hydrocarbons.
Alkenes-- These are unsaturated Hydrocarbons i.e. those
hydrocarbons that have one or more double bonds between carbon
atoms.
Alkynes -- Those with one or more triple bonds between carbon
atoms are called alkynes. These are mixed with alkanes in
petroleum and contribute more carbon dioxide per pound than the
saturated hydrocarbons.
Chemistry
Cycloalkanes – Any hydrocarbon containing one or more ring
structures
Aromatic Hydrocarbons – This class of molecules has specialized
ring structures where bonds between carbon atoms are an
intermediate between single and double bonds.
Chemistry of crude petroleum
When crude petroleum is extracted from the earth
it may be a mixture of hydrocarbons in solid, liquid
and gas states.
Short chain hydrocarbons like methane are gases.
Medium chain hydrocarbons like paraffin are
liquids.
Long chain hydrocarbons like bitumen are solids.
Hydrocarbons containing up to four carbon atoms
are usually gases, those with 5 to 19 carbon atoms
are usually liquids and those with 20 or more are
solids.
Chemistry
Hydrocarbons
containing
between 6 and 10
carbon molecules
are the top
components of
most fuels,
regardless of
whether they are
alkanes, alkenes,
or cyclic.
 What is Crude Oil?

Crude oils are in liquid form containing complex mixtures of
many different hydrocarbon compounds.
Crude oils vary in appearance and composition from one oil field
to another.
An "average" crude oil sample contains about 84% C, 14% H, 1-
3% S and less than 1% each of N, O, metals, salts and other
elements.
Crude oils are generally classified as paraffinic, naphthenic or
aromatic, based on the predominant proportion of hydrocarbon
molecules. 12
 Classification of Crude Oils
The oil industry classifies "crude"
 By the location of its origin (e.g., "West Texas Intermediate, WTI" or
"Brent") and
 Often by its relative weight or viscosity ("light", "intermediate" or
"heavy");
 Refiners may also refer it as "sweet," which means it contains relatively
little sulphur or as "sour," which means it contains substantial amounts
of sulphur and requires more refining in order to meet current product
specifications.
Each crude oil has unique molecular characteristics which are understood
by the use of crude oil sample analysis in petroleum laboratories. 13
 Classification of Crude Oils (continued)

These references are known as Crude oil benchmarks:
 Brent Crude, comprising 15 oils from fields in the Brent in North Sea.
 West Texas Intermediate (WTI) for North American oil.
 Dubai, used as benchmark for Middle East oil flowing to the Asia-Pacific
region.
 Tapis (from Malaysia, used as a reference for light Far East oil).
 Minas (from Indonesia, used as a reference for heavy Far East oil).
 The OPEC Reference Basket, a weighted average of oil blends from
various OPEC countries.

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Hydrocarbons in Crude Oils

Composition of Petroleum

15
 Basics of Hydrocarbon Chemistry

Crude oil is a mixture of hydrocarbon molecules, which are organic
compounds of carbon and hydrogen atoms that may include from one to 60
carbon atoms.
The properties of hydrocarbons depend on the number and arrangement of
the carbon and hydrogen atoms in the molecules.
Hydrocarbons containing up to four carbon atoms are usually gases, those
with 5 to 19 carbon atoms are usually liquids and those with 20 or more are
solids.
Main Hydrocarbons in Crude Oils: Paraffins, Aromatics, Naphthenes
(Cycloparaffins), Other Hydrocarbons (Alkenes, and Alkynes).

16
 Paraffins
The paraffinic series of hydrocarbon compounds found in crude oil have
the general formula CnH2n+2 and can be either straight chains (normal) or
branched chains (isomers) of carbon atoms.
Examples of straight-chain molecules are methane, ethane, propane and
butane (gases containing from one to four carbon atoms) and pentane
and hexane (liquids with five to six carbon atoms).

The Simplest Paraffin –
Methane CH4 n Butane and Isobutane - C4H10 17
 Aromatics

Aromatics are unsaturated ring-type (cyclic) compounds which react readily
because they have carbon atoms that are deficient in hydrogen.
All aromatics have at least one benzene ring as part of their molecular
structure.

Toluene (C7H8) Benzene (C6H6) Napthalene (C10H8) 18
 Naphthenes
Naphthenes are saturated hydrocarbon groupings with the general formula
CnH2n, arranged in the form of closed rings (cyclic) and found in all fractions
of crude oil except the very lightest.

19
PHYSICAL PROPERTIES OF
HYDROCARBONS

Color Specific gravity is the ratio of the density of a
substance to the density of a reference
Odor substance; ٧
Density
Specific Gravity The flash point is the lowest temperature at which a
substance vaporizes into a gas, which can be
Boiling Point ignited with the introduction of an external source of
fire.
Freezing Point
Flash Point Units – centipoises (μ, cp)
Viscosity Strongly temperature dependent
PHYSICAL PROPERTIES OF
HYDROCARBONS
Refractive Index
A property of a material that changes the speed of
light, ; It is calculated as the ratio of the velocity of
light in vacuum to its velocity in a specified medium.

˚ API gravity = 141.5 - 131.5
٧

٧ = specific gravity
 The Origin of Petroleum Oil & Gas; Theories
https://www.youtube.com/watch?v=pvH-h7TzSsE
The Organic Theory https://www.sciencelearn.org.nz/videos/800-oil-formation

According to the this theory, oil & gas originates from animals and plants
where beds of silt (containing tiny organisms), mud and sand were buried deep
beneath the earth. Geologists believe that high heat and pressure, bacteria,
chemical reactions and other forces transformed the organic remains into oil
and gas.

The Inorganic Theory
Hydrocarbons are formed by combination of carbon and hydrogen in the earth
rocks due to the influence of high temperature and pressure 22
Origin: Plankton
Plant Animal
Most of the world’s oil
plankton plankton
and gas is made up of

would fit on a pinhead!
10,000 of these bugs
the fossil remains of
microscopic marine
plants and animals.
That’s why oil and gas
are often referred to as
fossil fuels. Some oil and
gas may have also
originated from the Most oil and gas starts life as microscopic plants and animals
remains of land plants. that live in the ocean.
Origin: Black Shale
When plankton dies it slowly settles to the sea bed where it
forms an organic mush.
However, if there is little or no oxygen in the water then animals
can’t survive and the organic mush accumulates. Where
sediment contains more than 5% organic matter, it eventually
forms a rock known as a Black Shale
Origin: Cooking
As Black Shale is buried, it is heated.
Organic matter is first changed by the increase in
temperature into kerogen, which is a solid form
of hydrocarbon. At temperatures of around
30°C, a solid, sticky bitumen is produced.
Around 90°C, it is changed into a liquid state,
which we call oil

Around 150°C, it is changed into a gas
A rock that has produced oil and gas in this way is
known as a Source Rock
 Types of Rocks
The three main types, or classes, of rock are sedimentary, metamorphic,
and igneous and the differences among them have to do with how they are formed.

Sedimentary
Sedimentary rocks are formed from particles of sand, shells, pebbles, and other
fragments of material. Together, all these particles are called sediment. Gradually, the
sediment accumulates in layers and over a long period of time hardens into rock.
Examples of this rock type include conglomerate and limestone.
Metamorphic
Metamorphic rocks are formed under the surface of the earth from the metamorphosis
(change) that occurs due to intense heat and pressure (squeezing). The rocks that
result from these processes often have ribbon like layers and may have shiny crystals.
Examples of this rock type include marble.
Igneous
Igneous rocks are formed when magma (molten rock deep within the earth) cools and
hardens. Sometimes the magma cools inside the earth, and other times it erupts onto
the surface from volcanoes (in this case, it is called lava). When lava cools very quickly,
no crystals form and the rock looks shiny and glasslike. Examples of this rock type
include basalt.
Geological Conditions for Oil and Gas Formation

Most oil and gas accumulates in sedimentary rocks.
Sedimentary rocks (formed by sediment from surrounding
rock structures and water) are one of three main rock
groups (others are igneous and metamorphic rocks).
Sedimentary rocks covers 75-80% of the Earth's land area
and include common types such as chalk, limestone,
dolomite, sandstone, conglomerate and shale.
28
Rock Cycle https://www.geolsoc.org.uk/ks3/gsl/education/resources/rockcycle.html

29
 Sedimentary Rocks
Chalk is a soft, white, porous Limestone is a sedimentary rock Dolomite: is a sedimentary carbonate
sedimentary rock, a form of composed largely of the mineral rock and a mineral, both composed of
limestone composed of the calcite (calcium carbonate: calcium magnesium carbonate
mineral calcite CaCO3) CaMg(CO3)2 found in crystals.

Sandstone is a sedimentary rock Conglomerate is a rock consisting Shale is a fine-grained sedimentary
composed mainly of sand-size of individual stones that have rock whose original constituents
mineral or rock grains. become cemented together were clay minerals or muds.

30
 Properties of sedimentary rocks
Chalk is a soft, white, porous sedimentary rock, a form of limestone
composed of the mineral calcite.
It forms under relatively deep marine conditions from the gradual
accumulation of minute calcite plates
Limestone is a sedimentary rock composed largely of the mineral
calcite (calcium carbonate: CaCO3)
Dolomite: is a sedimentary carbonate rock and a mineral. Dolomites
are usually formed by recrystallization of original aragonite or calcite
crystals in sediments. Magnesium in the pore fluids replace some of
the calcium, forming a Mg-Ca carbonate structure.
 Properties of sedimentary rocks
Sandstone is a sedimentary rock composed mainly of sand-size
mineral or rock grains. Like sand, sandstone may be any color, but
the most common colors are brown, yellow, red, gray and white.
A conglomerate is a rock consisting of individual stones that have
become cemented together. Conglomerates are sedimentary rocks
consisting of rounded fragments.
Shale is a fine-grained sedimentary rock whose original
constituents were clay minerals or muds.
 Reservoir Rocks

A petroleum reservoir, or oil and gas reservoir, is a subsurface pool of
hydrocarbons contained in porous or fractured rock formations.

The naturally occurring hydrocarbons, such as crude oil or natural gas,
are trapped by overlying rock formations with lower permeability.

According to Society of Petroleum Engineers Glossary, a reservoir rock
is a rock containing porosity, permeability, sufficient hydrocarbon
accumulation and a sealing mechanism to form a reservoir from which
commercial flows of hydrocarbons can be produced.
33
 Reservoir Rocks
Porosity and permeability are important factors in reservoir formation.
Porosity The porosity of a rock is a measure of the storage capacity
(pore volume)that is capable of holding fluids. Quantitatively, the
porosity is the ratio of the pore volume to the
total volume (bulk volume). (e.g. Shale is less
porous and carbonate is more porous).
 Permeability is an intrinsic property of a material that determines
how easily a fluid can pass through it. In the petroleum industry,
the Darcy (D) is the standard unit of permeability, (a rock is
permeable when the pores are connected).
 Porosity and Permeability
Just as with porosity, the packing, shape, and sorting of granular materials
control their permeability.
Although a rock may be highly porous, if the voids are not interconnected,
then fluids within the closed, isolated pores cannot move.

https://www.youtube.com/watch?v=8YHsxXEVB1M
35
https://www.youtube.com/watch?v=5uyPY96jtxU
Reservoir Rocks (erosion and deformation)

For a rock to be an effective reservoir, it must contain
adequate porosity and permeability that is properly sealed
against erosion and tectonic (movement) destruction.
Many reservoirs and traps have been generated and
eliminated by erosion and deformation.
These are called dead oil.

36
Rock Type Distribution in the Earth Crust and Oil and
Gas Production by Rock Type

Carbonates 21% Class of sedimentary
rocks composed
Sandstone 37%
primarily of carbonate
Shale 42% minerals.
Two major types are:
Distribution of rock types 1) Limestone (CaCO3)
2) Dolomite
[CaMg(CO3)2]

Miscellaneous 2.5%

Sandstone 36%
Carbonates 61.5%
(more pores)
Production by rock types
37
 https://www.youtube.com/watch?v=iCTDSuDcyPw
Migration https://www.youtube.com/watch?v=nPOq7zUojqg

Hot oil and gas is less dense than the source
rock in which it occurs
Oil and gas migrate upwards up through the
rock in much the same way that the air bubbles
of an underwater diver rise to the surface
The rising oil and gas eventually gets trapped in
pockets in the rock called reservoirs

Rising oil
 Migration of Crude Oil

Even though shale is relatively impermeable, oil is created in its pores.

As tectonic forces moves the petroleum forming rocks out of there
birthplace, great pressures from overlying formations squeeze the
petroleum out of the relatively impermeable shale into cracks and
into more permeable formations such as sandstone (i.e. carbonate
rocks).

39
 Summary (Oil Migration)
Original
Organic
Matter

Kerogen

Mature
Crude Oil
Kerogen

Graphite Methane

Losing Hydrogen Gaining Hydrogen
40
 Oil and Gas Traps
If the rock containing the oil is very porous and very permeable, petroleum will escape.
Something must stop the oil from escaping and migrating.

A trap is any combination of physical factors that promotes accumulation and retention
Impermeable
of the petroleum in one location.

Some rocks are permeable and allow oil and gas

to freely pass through them but other rocks are

impermeable and block the upward passage of oil

and gas. This is one type of Oil Trap.
Permeable
41
 Types of Traps
Structural traps: These traps are types that form as a result of some
structural deformation - a bend or dip - of rock. These traps take on
several forms and shapes as a result of different types of
deformation. Shapes of dome, antiklines and faults are common
structures. Fault related features also may be classified as
structural traps if closure is present.
 Anticline Traps are formed by a folding of rock under pressure
and compaction. Specifically, a sandstone bed covered with low
permeability shale is folded into a trap that contains petroleum
products. Hydrocarbons are trapped in the peak of this fold
 Fault Traps are formed when reservoir rock is split along a fault
line. Between the walls of the split reservoir, clay traps oil and
prevents it from leaving the trap
43
 Salt Dome traps are formed as a result of below ground salt - which is
less dense than the rock above it - moving upwards slowly and deforming
the rock along the way. The process of this salt deforming rock is known as
salt tectonics. Oil and gas that flows through the reservoir rock will come to
rest when it reaches the salt dome and is then trapped
Impermeable
 Types of Traps
Stratigraphic traps are formed when other beds seal a
reservoir bed or when the permeability changes within the
reservoir bed itself. There are two main types

 Primary stratigraphic traps result from changes that
develop during the sedimentation process. These are
structural changes that arise as a result of discontinuous
deposition of sediment.

 Secondary stratigraphic traps result from changes that
develop after sedimentation has occurred. These changes
can involve changes in porosity of the rock that lead to
formation of a cap-like rock. 45
https://www.youtube.com/watch?v=_PDOD_FEnNk

https://www.youtube.com/watch?v=_PDOD_FEnNk
 Exploration Methods
Exploration was once a matter of good luck and guess
work.
Most successful method was to drill near an oil seeps
(where oil is actually present on the surface).
Now it uses many techniques and scientific principles.
Today, surface and subsurface study is the leading
technology in discovering oil and gas.
Aerial and satellite images and other instrumentation are
used to gather information that helps determine where to
drill.
47
 Exploration Methods (continued)
Then specialist examine the rock fragments and core
samples brought up while drilling the well and
running special tools into the hole to get more
information about the formation and possible oil or
gas traps.
Finally examining, correlating and interpreting the
information and the data makes it possible for the oil
companies to accurately locate structures that may
contain hydrocarbon and if the hydrocarbons are
worth exploiting.
48
 Exploration Methods Summary
Exploration methods include:

1. Surface geological studies
2. Oil and gas seeps.
3. Geophysical surveys (e.g. seismic surveys)
4. Reservoir development tools

49
 Geophysical, Geochemical, and Direct
Exploration Techniques
Geophysical Exploration Techniques
Seismic reflection and refraction,
gravity surveys
magnetic survey using proton magnetometer
electrical resistivity
Geochemical Exploration Methods
Satellite images
soil sampling
stream sampling
Direct Exploration Methods
Drilling
Exploration and Production: Seismic Surveys
Drill here!

Seismic surveys are used to locate likely rock structures
underground in which oil and gas might be found.
Shock waves are fired into the ground.
These bounce off layers of rock and reveal any structural
domes that might contain oil.
 Seismic Reflection
This technique is used extensively in oil exploration as
well as for metal ores.
The seismic reflection method works by bouncing sound
waves off boundaries between different types of rock.
The reflections recorded are plotted as dark lines on a
seismic section.
This method can be implemented both on land and at
sea.
It shows up rocks with contrasting densities so ores show
up well as well as less dense rocks like salt.
Mapping
If rocks are exposed at the surface then
mapping them can give a clear indication
of the geology not only on the surface
but also underground.
You may be able to work out an
underground cross section.
Digital images of the subsurface layers
and faulted structures are created. Even
details of past environments, such as
river channels on ancient flood plains or
sediments on the former deep-ocean
floor, can be identified and mapped
Exploration and Production: Drilling the well
Once an oil or gas prospect
has been identified, a hole
is drilled to assess the
potential.
The cost of drilling is very
great. On an offshore rig,
it may cost $20,000 for
each metre drilled.
A company incurs vast
losses for every “dry hole”
drilled.
Direct exploration methods
Drilling
 Drilling in an area is often the only way
of being absolutely sure what is
underground.
 The geochemical and geophysical
methods will give a clue.
 Analysing the samples and noting the
depths at which rocks occur can help in
deciding whether an ore is worth
mining or not.
 Drilling is only used in areas that have
been selected as "targets" from
geological, geophysical and/or
geochemical methods.
Rotary drilling
Rotary drilling is a technique which employs a
rotating drill bit that grinds/pulverizes the
soil/rock as the drill bit advances
Then it uses a medium (such as compressed air,
water, or drilling mud) to transport the drill
cuttings up to the ground surface.
Rotary drilling is most commonly associated
with water and oil well drilling
 Types of Drilling
Conventional Drilling
Conventional wells are drilled vertically from the surface straight
down to the pay zone. This is the traditional and still common
type of drilling.
Horizontal Drilling
Using technologies such as bottom driven bits, drillers are able to
execute a sharp turn and drill horizontally along a thin pay zone.
Slant Drilling
Drilling at an angle from perpendicular (commonly 30° to
45°). This approach minimizes surface environmental
disturbance.
Directional Drilling
Drilling has advanced from slant and horizontal drilling to drilling
that can change direction and depth several times in one well
bore.
 Left to right; Conventional, Slang, horizontal
58
 Well Logs and Sample Logs
Reservoir Development Tools
When a surface and subsurface information of a
formation indicates a strong possibility of hydrocarbon
existence, an oil company may then drill an exploratory
well or wells.
As the drilling progresses, underground rocks are then
tested by means of core sampling and well logs.
The gathered data determines whether the reservoir
has enough oil or gas to justify completing the
exploration and then production. 59
 Reservoir Development Tools (continued)
Well logs are records that give information about the
formation through which a well has been drilled.
The log gives the geophysical and other information of
a well per depth.

60
 Types of Well Logs
1. Well Logs:

Driller’s log
Wireline log (Electrical log, Nuclear log, Acoustic
log)
 Electrical log (resistivity, induction)
2. Sample logs:
Core Samples
Cutting Sample

61
 1. Well Logs
Driller’s log
It’s the most common log where the log contains
information about the kind of rocks and fluids
encountered at different depths.
It gives also gives information when the formation is
altered from soft to hard rock.
It gives an idea of how long it takes to drill the well (for
future drilling purposes).
Gives other formation issues encountered during
drilling. 62
 1. Well Logs (continued)
Wireline log
A wireline is a metal cable (line) that run through the
well hole with several tools attached to it.
Each tool takes a different measurement.
Each measurement gives an indirect information about
the formation down the well.
Wireline logging often involves complex calculations
and interpretations of the data provided from the tool.
Oil service companies (e.g. Schlumberger, Baker Atlas,
Halliburton) uses the information to decide if the oil or
gas in the well is economically feasible. 63
 1. Well Logs – Wireline logs (continued)
There are different types of wireline logs: Electrical Logs,
Nuclear Logs, Acoustic Logs.
A) Electrical Logs
Electric logging measures the formation resistivity or
conductivity and the spontaneous potential.
Induction Log: records conductivity (weak current) that
flows in the rocks. It gives an idea about the thickness
and boundary of each layer in the borehole (called
spontaneous potential log i.e. SP log).
64
 1. Well Logs – Wireline logs (continued)
Resistivity Log: records resistance in the borehole
(hydrocarbons do not conduct electricity while all
waters do).
Both the brine in the pore space and the water bound
to the clay in formation rocks conduct electric current.
The measured conductivity reflects the presence of
brine in the rock and water bound to clay minerals.
Formations with very low porosity or whose porosity is
occupied by nonconductive oil and gas are identified
by high resistivity segments in electric logs.
65
 1. Well Logs – Wireline logs (continued)
B) Nuclear Logs
Several types of radioactivity logs measure the natural
radioactivity of the formation, while others emit
radioactive particles and measure the response from the
formation.
Gamma ray log:
 Measures radioactivity to determine what type of rocks
are present in the well. For example shale emits more
radioactive elements than sandstone.
 In general, K, U and Th are the primary contributors to
natural radioactivity in the sedimentary formations.
These elements primarily occur in clay minerals. 66
 1. Well Logs – Wireline logs (continued)
Neutron log:
 The tool sends atomic particles (neutrons) through the
formation. When the neutrons collide with hydrogen, the
hydrogen slows them down.
 When the detector records slow neutrons, it means that
there more hydrogen is present (i.e. maybe more
hydrocarbons than water).

67
 1. Well Logs – Wireline logs (continued)
C) Acoustic Logs
It gives information about the density of the rocks (how
dense the rock is).
The acoustic or sonic log records how fast sound travels
through a rock.
The speed of sound traveled depends on how dense a
formation is and how much fluid it contains.
Example: shale is less porous therefore the sound will
travel faster and you will get a high acoustic signal back.
(e.g. of signal on the board)
68
 2. Sample Logs
Sample logs:
 Core Samples
 Cutting Sample
Core samples
 A core is a cylindrical column of rock that shows the
sequence of rocks as they appear within the earth.
 It provides the most accurate information about the
underground formation about porosity, permeability,
composition, fluid content and geological age. 69
 2. Sample Logs (continued)
Cutting samples
 As a regular bit drills a hole, it breaks up the rock into pieces
called cuttings. The cuttings flow out of the hole where
geologists can use them to analyze the rock being drilled.
 Since cuttings are fragments of rocks and do not form a
continuous sample like a core, they are not as useful cores
are to the geologists.
 Cuttings may not all come from the bottom of the hole but
may include pieces of formations that have sloughed off
closer to the surface.
 Even with these limitations, however, cuttings can provide
useful data and are regularly examined during drilling. 70
Exploration and Production: Primary and
Enhanced Recovery
Although oil and gas are less
dense than water and
naturally rise up a well to the
surface, in reality only 40-
50% of the total will do so.
To enhance recovery, a hole
is drilled adjacent to the well
and steam is pumped down.
The hot water helps to push
the oil out of the rock and up
into the well.
Exploration and Production: Enhanced Recovery
Primary Recovery - 20 to 30% of oil in reservoir.
 Least expensive
 Uses natural pressure supplied by:
o Water, Gas cap, Solution gas
Secondary Recovery (Enhanced Oil Recovery) increases
production to 50-60%
Water injection, gas re-injection

72