Nomitech Oil & Gas Projects Cost Estimation Training ... · Oil & Gas Projects Cost Estimation...
Transcript of Nomitech Oil & Gas Projects Cost Estimation Training ... · Oil & Gas Projects Cost Estimation...
Oil & Gas Projects
Cost Estimation
Training Courses
2013
Technical Training Courses on
CostOs Assemblies Onshore & Offshore
Upstream, Midstream and Downstream June 2013
Nomitech
Cost Estimation
In cost estimating,
there are certain principles,
practices and procedures
that hold true whether it is
an industrial process, a
manufactured product, a
multimillion dollar project,
or a business service that is
being estimated.
These courses are a
straightforward exposition
of those basic concepts and
steps required to develop
Resource, Analogy, Market
based, Trend, factorial and
parametric type estimates.
The techniques
presented are a necessary
component of the repertoire
of skills of professionals of
any business organization
that is interested in
consistently making a profit
and achieving the
maximum result for the
dollars spent.
The courses are
designed to be equally
helpful to those who work
at small firms, large
corporations, or
government agencies.
These courses will provide
you with specialist Training
in oil and gas cost
estimation.
It will equip you with the
theoretical and practical
knowledge and skills
required to solve and
manage oil and gas cost
simulation and complexities
and engineering problems at
optimum cost and to
optimize existing processes
with increased efficiency.
These courses will provide
you with specialist Training
in oil and gas cost
estimation.
It will equip you with the
theoretical and practical
knowledge and skills
required to solve and
manage oil and gas cost
simulation complexities and
estimation problems to
optimize existing processes
with increased efficiency.
Why participate in these
courses?
The program will provide you with
the knowledge and skills for a wide
range of professional opportunities in
national and multinational oil and gas
companies and consultancies.
On successful completion of the
program, you will get the opportunity
to acquire the Nomitech and Dione Oil
Co. International Technical Certificate
in Oil and Gas projects cost estimation.
What are the course
contents?
The course will
present estimation
methods, AACE
classification,
CostOs tools,
Assemblies, Cost
Models, NoDoC, and
Economic analysis of
Oil & Gas projects
in three levels
Conceptual, Basic
and Detailed for Up-
stream, Mid-stream
and Down-stream
both for on-shore
and off-shore covers
exploration,
development,
production and
abandonment.
The Program
The participants are
divided into companies. ,
each company will
prepare cost estimate and
bid for sample project
using CostOs Cost Models.
Class time will be
provided for students to
work collaboratively on
their projects.
Estimates will be
opened at the final class
session. High level
students will prepare a
formal presentation and
supporting submittal for
the class which will
outline their approach to
the project.
The presentation is
expected to be of high
quality, suitable for
delivery to the top
management of an owner
organization.
Estimate the cost of
sample project using
CostOs Cost Models and
Cost Simulator by own and
compare the result by
analyzing the Market prices
Topics - Offshore
Offshore
Upstream
Reservoir Eng.
Geology
Geophysics
Well Testing
Petrophysics
Exploration
Evaluation
Geology
Geophysics
Geochemistry
Petrophysics
Simulation
Valuation
Drilling
Casing/Tubing
Tools/ Accessories
Technologies
Platforms
Services
Vessels
Rigs
Fluids
Completion
Logging
Estimulation
Sand
Control
Sediment Prevention
Wellhead Facilities
Production
Platforms
Units
Flares
Facilities
Utilities
Enhanced Recovery
Termal Methods
Non-Thermal
ESP
Wellsite Optimazation
Technical Assessment
Economic Analysis
Midstream
Transportation
Pipelaying
Tanks
Vessels
Ships
FPSO
Storage
Liquid Storage
Gas Storage
FPSO
Reinjection
Marine
Loading Arm
Offshore
Upstream
Reservoir Eng.
Geology
Geophysics
Well Testing
Petrophysics
Exploration
Evaluation
Geology
Geophisics
Geochemistry
Petrophysics
Simulation
Valuation
Drilling
Casing/Tubing
Tools/ Accessories
Technologies
Platforms
Services
Vessels
Rigs
Fluids
Completion
Logging
Estimulation
Sand
Control
Sediment Prevention
Wellhead Facilities
Production
Platforms
Units
Flares
Facilities
Utilities
Enhanced Recovery
Termal Methods
Non-Thermal
ESP
Wellsite Optimazation
Technical Assessment
Economic Analysis
Midstream
Transportation
Pipelaying
Tanks
Vessels
Ships
FPSO
Storage
Liquid Storage
Gas Storage
FPSO
Reinjection
Marine
Loading Arm
Onshore
Upstream
Reservoir Eng.
Geology
Geophysics
Well Testing
Petrophysics
Exploration
Evaluation
Geology
Geophysics
Geochemistry
Petrophysics
Simulation
Valuation
Drilling
Casing/Tubing
Tools/
Accessories
Technologies
Services
Vessels
Rigs
Fluids
Completion
Logging
Estimulation
Sand Control
Sediment Prevention
Wellhead
Facilities
Production
Units
Flares
Facilities
Utilities
Enhanced Recovery
Termal
Methods
Non-Thermal
ESP
Wellsite Optimazation
Technical Assessment
Economic
Analysis
Midstream
Processing
Gathering
System
Separation
Treatment
Dehydration
Desalination
Chemical
Injection
Transportation
Pipeline
(Oil / Gas)
Tanks
Rail
Storage
Liquid Storage
Gas Storage
Reinjection
Uderground Storage
Down Stream
Refining Oil
Desalting
Distillation
Hydro Treating
Reforming
Isomerization
Vaccum
Distillation
Alkalization
Visbreaking
Cracking
Cooking
Refining Gas
Condenced
Removal
Acid Removal
Dehydration
Mercury
Removal
Nitrogen
Rejection
NGL Recovery
Fractionation
Gas
Sweetening
Tail Gas
Treating
Distribution
Resindential
Commercial
Power
Generation
Industrial
Agricultural
Sub- Products
Basic Units
Intermediate
Unite
End Units
Down Stream
Units
Utilities
Topics- Onshore
Module Code Module Title Cost Models & Cost Simulation
GCST Cost Estimation Tools Methodology, Classifications and CostOs
FUEX-1 Exploration-1 Evaluation, Simulation, Valuation
FUEX-2 Exploration-2 Geology , Geophysics, Geochemistry, Petrophysics
FUDR-1 Drilling-1 Technologies, Methods Selection
FUDR-2 Drilling-2 Bits, Casing/Tubing, Tools/Accessories
FUDR-3 Drilling-3 Services, Fluids
FUDR-4 Drilling-4 Offshore Rigs, Offshore Vessels
FUDR-5 Drilling-5 Onshore Rigs, Onshore Drilling Facilities
FUCP-1 Well Completion-1 Logging, Stimulation, Sand Control, Sediment Prevention
FUCP-2 Well Completion-2 Wellhead Facilities
FUPR-1 Production-1 Offshore Platforms, (Wellhead, Production, Bridges, Flares)
FUPR-2 Production-2 Facilities, Utilities
FUER-1 Enhanced Recovery-1 Thermal Methods, Non Thermal Methods, ESP
FUER-2 Enhanced Recovery-2 Well Site Optimization, Technical Assessment
ECO-01 Production and EOR Economic Analysis
FMTP-1 Transportation-1 Offshore Pipelaying, Offshore Vessels
FMTP-2 Transportation-2 FPSO
FMTP-3 Transportation-3 Oil & Gas Pipelines
FMTP-4 Transportation-4 Tankers, Rail
FMST-1 Storage-1 Liquid Storage, Gas Storage
FMST-2 Storage-2 FPSO, Underground, Marine Loading Arm
NMPC-1 Processing-1 Gathering System, Separation, Compression
NMPC-2 Processing-2 Treatment, Dehydration
NMPC-3 Processing-3 Desalination, Chemical Injection
NMTP-1 Transportation-1 Pipeline( Oil/Gas)
NDRO-1 Refining Oil-1 Desalting, Distillation
Training Modules
NDRO-2 Refining Oil-2 Hydro Treating, Reforming
NDRO-3 Refining Oil-3 Isomerization, Vacuum Distillation
NDRO-4 Refining Oil-4 Alkalization, Visbreaking
NDRO-5 Refining Oil-5 Cracking, Cooking
NDRG-1 Refining Gas-1 Condensed Removal, Acid Removal
NDRG-2 Refining Gas-2 Dehydration, Mercury Removal
NDRG-3 Refining Gas-3 Nitrogen Reinjection, NGL Recovery
NDRG-4 Refining Gas-4 Fractionation, Gas Sweetening
NDRG-5 Refining Gas-5 Tail Gas Treating
CostOs implements
AACE classifications
and different
estimation
methods by its
various tools.
Cost Estimation Tools
(Training Module Code: GCET)
About The Course:
1. An Introduction to Cost Estimation
- In This section we will discuss about the cost
estimation history, its importance, necessities
and know how's.
2. Cost Estimation Methods
- There are variety of cost estimation methods,
based on their application and point of view.
Various methods will be explained here in this
part.
3. AACE and Classification
- Association for the Advancement of Cost
Engineering has developed 5 classes of cost
estimation, based on decision making
parameters. These parameters will be explained
briefly.
4. CostOs, AACE and Methods
- We will show how CostOs implements AACE
classifications and estimation Methods for
projects.
5. CostOs Tools
- CostOs tools which provide cost estimation by
different methods will be reviewed.
6. An Introduction to NoDoC
- In this part, NoDoC will be introduced as
a cost estimation database.
7. Oil & Gas Projects Economic Analysis
- 5 classes of AACE are shrunk to 3
classes in O & G projects because of the
nature of O & G projects. Alternatively
we will show the ability of assemblies for
economic analysis of the O & G projects.
8. Upstream Projects Cost Estimation
Using CostOs
- The cost of sample "Drilling" and
"Exploration" projects will be estimated
by CostOs assemblies in three main
classes and various methods.
9. Midstream Projects Cost Estimation
Using CostOs
- The cost of sample "Gas Gathering
unit, compression station and gas
pipeline" project will be estimated
by CostOs assemblies in three main
classes and various methods.
10. Downstream Projects Cost
Estimation Using CostOs
- The cost of sample "Gas Processing
Plant" project will be estimated by
CostOs assemblies in three main classes
and various methods.
Case studies are
available in all 3 oil and
gas sectors, Upstream,
Midstream and
Downstream.
Course Content:
1. An Introduction to Cost Estimation
- Cost Estimation position in project management
- Required time and expenses for cost estimation of project
2. Cost Estimation Methods
- Different references have classified cost estimation methods in various grouping.
Method 1.
- Detailed Estimating Method
- Parametric
- Cost Estimation Relationships
End Product Unit Method
Physical Dimension Method
Ratio or Factor Method
- Other Methods Level of Effect
Analogy
Expert Opinion Method
Trend Analysis Method
Learning Curve
- Methods for Estimating Other Life-Cycle Costs
Percentage Method
Count Drawing & Specifications
Full-time Equivalent Method
Method 2.
- Qualitative Method Intuitive Case- Based Methodology
Decision Support System
Rule-Based
Fuzzy Logic Approach
Expert System
Analogical Regression
Analysis Back Propagation Neural Network
- Quantitative Method Parametric Method
Analytical Method Operation Based Approach
Break Down Approach
Tolerance Based
Feature Based
Activity Based
Method 3.
Expert Judgment
Analogous Estimating
Parametric Estimating
Bottom-Up Estimating
Three-Point
Reserve Analysis
Vendor Bid Analysis
3. AACE and Classification
- Classification Parameters:
- Level of Project definition
- End Usage
- Expected Accuracy
- Methodology
- AACE 5 to 1 Classes
4. CostOs, AACE and Methods
- Review on CostOs
- Comparison of CostOs and AACE and how CostOs supports different methods of cost estimation &
AACE classification
5. CostOs Tools
- CostOs has various tools for different cost estimation methods which are:
- Assemblies
- Resource Allocation
- Trends
- Analogy
6. CostOs Assemblies
- How assemblies work
- Different methods that can be used in assemblies
7. An Introduction to NoDoC
- What is NoDoC
8. Oil and Gas Projects Economic Analysis
- Differences of oil and gas projects cost estimation in comparison with other industries
- Classification in oil and gas projects cost estimation
9. Upstream Projects Cost Estimation using CostOs
- Case Study: "Drilling" Project
- Case Study: "Exploration" Project
10. Midstream Projects Cost Estimation using CostOs
- Case Study: "Gas Gathering Unit" Project
11. Downstream Projects Cost Estimation Using CostOs
- Case Study: "Gas Production Plant" Project
12. Summary
Training Module Code (FUEX-2):
Geology:
NoDoC Cost models support:
• Reservoir Database Review
• Reservoir Validation with dynamic data
• Reservoir Seismic/log interpretation
• Reservoir 1-D stratigraphic and facies analysis
• Reservoir 2-D correlation and facies analysis
• Reservoir Facies proportion curves exploration
• Reservoir Depositional model
Geology is commercially important for mineral and hydrocarbon exploration and for
evaluating water resources; it is publicly important for the prediction and understanding of
natural hazards, the remediation of environmental problems, and for providing insights into
past climate change; plays a role in geotechnical engineering; and is a major academic
discipline.
Geologists are responsible for finding oil. Their task is to find the right conditions for an oil trap
-- the right source rock, reservoir rock and entrapment. Many years ago, geologists interpreted
surface features, surface rock and soil types, and perhaps some small core samples obtained by
shallow drilling. Modern oil geologists also examine surface rocks and terrain, with the
additional help of satellite images. However, they also use a variety of other methods to find oil.
They can use sensitive gravity meters to measure tiny changes in the earth's gravitational field
that could indicate flowing oil, as well as sensitive magnetometers to measure tiny changes in
the earth's magnetic field caused by flowing oil. They can detect the smell of hydrocarbons
using sensitive electronic noses called sniffers. Finally, and most commonly, they use seismology,
creating shock waves that pass through hidden rock layers and interpreting the waves that are
reflected back to the surface. In seismic surveys, a shock wave is created by the following:
• Compressed-air gun
• Thumper truck
• Explosives
The shock waves travel beneath the surface of the Earth and are reflected back by the various
rock layers. The reflections travel at different speeds depending upon the type or density of
rock layers through which they must pass. Sensitive microphones or vibration detectors detect
the reflections of the shock waves -- hydrophones over water, seismometers over land.
Seismologists interpret the readings for signs of oil and gas traps.
Once the geologists find a prospective oil strike, they mark the location using GPS coordinates
on land or by marker buoys on water.
NoDoC provides data and models for estimation of Geology Sector of Oil & Gas exploration.
Geophysics:
Exploration Geophysicists use geophysics to find oil and gas, where drilling rig, production
platform, seismic ship are in background. A lot of preparation is required to get the energy source,
recording devices, recording truck, trace the path of the energy, some reflected, some transmitted.
In previous generations, they used to have wide, high-impact cut lines. Today, in environmentally
sensitive areas, hand cut, low-impact cut lines are used; supported by helicopters, and hence not as
much heavy equipment.
The NoDoC Cost Models offer cost data for estimating this aspect of the exploration process. The
models use probability functions for estimation. Proven reserves exist where there is a sufficient
body of supporting data from geology, geophysics, well tests, and field production to estimate the
extent of the oil or gas contained in the body of rock. They are deemed, “commercially recoverable,
from a given date forward, from known reservoirs and under current economic conditions,
operating methods, and government regulations.” Proven reserves can be developed or
undeveloped. Probable reserves are unproven reserves, but geological and engineering data suggest
that they are more likely than not to be recoverable. Statistical methods are often used in the
calculation of probable reserves, and the deciding criterion is usually that there should be at least a
50% probability that the quantities actually recovered will “equal or exceed the sum of estimated
proved plus probable reserves.” Probable reserves can be in areas adjoining proven or developed
fields or isolated from developed fields, but with drilling and testing data that indicates they are
economic with current technology. Possible reserves are unproved reserves that are less likely to be
recoverable than probable reserves, based on geological and engineering data analysis. Statistically,
they are defined as reserves that, if recovered, have – at most – a 10% probability of equaling or
exceeding the sum of the estimated proven, probable, and possible reserves. Possible reserves have
few, if any, wells drilled; and the reservoir has not been produced, or even tested. However, the
reservoir displays favorable geology and geophysics, and its size is estimated by statistical analysis.
Possible reserves can also be in areas with good data to indicate that oil and gas are present, but
they may not be commercially developable, or the technology to develop them may not exist (but
such technology improvements can reasonably be expected in the future). Although this sounds
very speculative, there is such a long history of oil and gas production that these estimates are
regarded with a fair degree of confidence.
Geochemistry:
Through field tests in low permeability crystalline rock, researchers have made significant
progress in understanding reservoir characteristics, including fracture initiation, dilation
and propagation, thermal drawdown, water loss rates, flow impedance, fluid mixing, and
fluid geochemistry. In addition to using hydraulic stimulation methods to establish
connectivity in the far field, it is feasible to create permeability near injection or production
wellbores by explosive fracturing, chemical leaching, and thermal stress cracking.
Geochemistry at low temperatures can be a benign factor, but as the salinity and
temperature increase, it may pose difficult engineering challenges. Considerable effort is
now going into the numerical modeling of coupled geochemical processes, but generally
there is still a lack of data to support the verification of the models. Dissolution and
precipitation problems in very high temperature fields are not well understood.
Conventional means of overcoming these problems by controlling pH, pressure,
temperature, and the use of additives are widely known from experience at hydrothermal
fields. Some laboratory studies may shed light on the processes involved; however, solutions
to specific geochemical problems will have to be devised when the first commercial fields
come into operation.
NoDoC models the estimation of cost of such operations using data and resources. It is
something like research and testing procedure and the related cost is widely depend on the
how deep are these researches.
Petrophysics:
Petrophysics is more than just "log analysis". Petrophysics is the description of the oil and/or gas
distributions and production flow capacity of reservoirs, from interpretations of pore system and
fluid interactions using all available data .
Petrophysicists use acoustic and density measurements of rocks to compute their mechanical
properties and strength. They measure the compressional (P) wave velocity of sound through the
rock and the shear (S) wave velocity and use these with the density of the rock to compute: The
rocks compressive strength which is the compressive stress that causes a rock to fail. The rocks
flexibility, the relationship between stress and deformation for a rock. Converted-wave analysis is
also used to determine subsurface lithology and porosity. These measurements are useful to design
programs to drill wells that produce oil and gas .
Coring and core analysis is a direct measurement of petrophysical properties. In the petroleum
industry rock samples are retrieved from subsurface and measured by core labs of oil company or
some commercial core measurement service companies. This process is time consuming and
expensive, thus cannot be applied to all the wells drilled in a field.
Well Logging is used as a relatively inexpensive method to obtain petrophysical properties
downhole. Measurement tools are conveyed downhole using either wireline or LWD method.
Any method that is used for Petrophysics requires various resources, manpower, equipment,
material and consumables. The NoDoC Cost Model for this most important aspect includes a
centeral database that guides users to do the estimate before participation in the process.
Training Module Code (FUDR-1):
Technologies:
For making hole, Oil & Gas well drilling, different
technologies have been invented.
Percussion drilling
- Rope
Drillstring
- With mud
- Without mud
Rotating bit
- Full cross-section drilling
Surface driven
Rotary drilling
Rotary nozzle drilling
Subsurface driven
Turbine drilling
Positive displacement motor drilling
Electro motor drilling
- Annular drilling
Diamond coring
Shot drilling
Special techniques
- Abrasive jet drilling
- Cavitating jet drilling
- Electric arc and plasma drilling
- Electric beam drilling
- Electric disintegration drilling
- Explosive drilling
- Flame jet drilling
- Implosion drilling
- Laser drilling
- REAM drilling
- Replaceable cutterhead drilling
- Rocket Exhaust drilling
- Spark drilling
- Subterrene drilling
- Terra drilling
- Thermal-mechanical drilling
- Thermocorer drilling
NoDoC covers cost
models for all drilling
technologies but have
special focus on the
rotary drilling
technology.
Drilling Technologies
Precussion Drilling
Rope
Drillstring
With Mud
Without Mud
Rotating Bit
Full-Cross Section Drilling
Surface Driven
Rotary Drilling
Rotary Nozzle Drilling
Subsurface Driven
Turbine Drilling
Positive Displacement Motor Drilling
Electro Motor Drilling
Annular Drilling
Diamond Coring
Shot Drilling
Special Techniques
Abrasive Jet Drilling
Cavitating Jet Drilling
Electric arc and plasma drilling
Electric beam drilling
Electric disintegration
drilling
Explosive drilling
Flame jet drilling
Implosion drilling
Laser drilling
REAM drilling
Replaceable cutterhead drilling
Rocket Exhaust drilling
Spark drilling
Terra drilling
Subterrene drilling
Thermal-mechanical
drilling
Thermocorer drilling
Training Module Code (FUDR-2):
Casing/Tubing:
NoDoC model for estimation of casing and tubing are based on the following criterias and fundamentals that
are used in many years for drilling engineering and operation.
In the past few years, man is forced to dig a well and aqueduct for exploiting the underground waters, but
caving of well, during and after digging was one of major problems in operating of this process the first
solution was overlaying of wells. Due to lack of waterproof overlays and mortars, the possibility of well
caving wasn’t diminished but it postponed for a short period. Next solution was reverting the wall of well and
using brick revetments are entire from many years ago.
In drilling process of oil and gas well, running of casing to protect the wall of well against caving and
penetrating of the fluids which are under pressure in ground structure is essential. Initially iron has been used
as a casing but today, because of its corrosion and related problems, casings are made of various steel alloys.
Casing running methods of oil and gas wells have been developed and complicated in recent years. In
seeking for more oil and gas, deep wells have been drilled and also methods of casing running developed to
overcome many hard conditions, in the depths of ground.
1. Casing
Casing is very resistant steel pipe and made of alloy steel , which is used in oil and gas wells with three
length ranges (16-25,25-34 and 34-38 ft) casing is a part of oil and gas industry (OCTG-Oil country tubular
goods(
Generally the casing performs six important functions, as follows:
1. Prevent caving and eroding of the well
2. Prevent contamination of fresh water by the fluids of lower layers and drilling fluid
3. Parting of formations from each other
4. Confine production to one formation
5. Provide required information for controlling the pressure of well
6. Establishing of a path for produced fluids
1.1. Various casing strings
According to usage various casing strings consist of:
1.1.1. Surface casting string
Surface casing prevents the weak formations that are encountered at shallow depth. it is also
very important to isolate the fresh water and prevent its contamination by drilling fluid and
fluids of lower layers . The length of surface casing string may be just 200 ft but in some cases
and according to local conditions, the length may be increased to thousands of feet.
1.1.2. Intermediate casing string
The most important purpose of using this string is protection of well and so it is called
protection casing string several intermediate casing strings usually used for one well . This
string may extend from surface to depth of 7,000 ft.
1.1.3. Production casing string
Production casing string isolates producing zones, provides reservoir control , and permits
selective production in multi zone production , also this string protects tubing . This string
usually is the longest, heaviest and the last string, so it shall be made of resistant alloy steel
pipes. on the other hand, a little leak may cause the blowout of well . So threaded joints of
production casting shall be resistant against probable pressures.
1.2. Exerted stresses to casing
When casing is running in a well, it is subjected to three significant forces. These forces
resulted from below stresses.
1.2.1. Tensile tension
This tension results from weight of casing string and causes tensile of pipe, also collapse
strength of pipe will be decreased for tensile tension.
1.2.2. Collapse pressure
Collapse pressure is defined as external pressure that tends to collapse the casing and results
from hydrostatic pressure. Collapse of casing string often occurs in cement injection process.
1.2.3. Burst pressure
Burst pressure is defined as internal pressure that tends to burst the casing. Generally, burst
pressure is high in upper casing (near the surface).
1.3. Technical specification of casing
Casing is classified according to these 5 characteristics:
1. The outside diameter
2. The wall thickness
3. Materials
4. The type of joint
5. The length range
Unit weight of pipe length is another characteristic which is determined according to wall thickness and
outside diameter. Technical specifications of casing are selected in accordance with API SPEC 5CT.
1.4. Grades of casing
API SPEC 5CT recognizes ten grades of casing.
1.4.1. Mechanical specifications
Grade of casing is specified according to its yield strength. Group, grade, yield strength and mechanical
specifications have been presented the yield strength shall be the tensile stress to produce a total
elongation of the gauge length, as determined by an extensometer.
Sometimes, defined grades do not meet the requirements (for example: well with high corrosion) to
solve this problem, manufactures of casing furnish pipes with special specification which are called non-
API casing grades. Some samples of
1.4.2. Chemical composition
Pipes and couplings which are produced according to API SPEC 5CT, shall be met the chemical
requirements, mentioned in table, numbers are based on percentage of weight.
1.5. Casing dimensions and weight specifications
According to API SPEC 5CT, there are two types of joints for casing which their dimensions and
specifications are selected in accordance with API SPEC 5CT.
Tools/Accessories:
NoDoC has provided cost estimation models for the following tools and accessories, downhole
equipment, which are used before, while and after oil & gas drilling process:
- CASING HEAD
- CASING HEAD SPOOL
- CASING & TUBING HANGERS
- AUTOMATIC AND UNITIZED CASING HANGERS
- EXTENDED NECK AND WRAP AROUND HANGERS
- DUAL SPLIT TYPE AND EXTENDED NECK TYPE HANGERS
- TUBING HEAD ADAPTERS
- TUBING HANGER SPOOL & COUPLING
- BOTTOM PACK-OFF CROSS OVER SEAL
- TUBING HEAD
- TUBING HEAD SPOOL
- Tools & Service Equipment
- Casing Head Body Retrievable Wear Bushing
- Retrieving Tool
- BOP Test Plug
- Back Pressure Valve
- Flanged Drilling Spool
- Valve Removal Plugs
- Valve Removal Tool
- Lubricator
- Choke Valves
- H2 Type Choke Valve
- Positive Choke, Choke Bean and Bean Wrench
- External Sleeve Control Choke
- Gate Valves
- Manual Gate Valves
- Flanged and Threaded
- High Temperature Gate Valve
- Flanged Gate Valve Part List
- Slab Style Gate Valves
- Flanged and Threaded
- Slab Gate Valve Part List
- Single & Dual Completion Well Head & X-Mass Tree Assemblies
- Choke and Kill Manifold
- X-mass Tree Cap
- Single Completion Component
- Safety Valve Landing Nipple
- Separation Sleeve
- Surface Controlled Subsurface Safety Valves (SSSV)
- TOOL TRAPS
- GREASE / OIL INJECTION SUPPLY SYSTEM
- WELLHEAD FLANGE ADAPTERS
- API ADAPTERS
- QUICK UNION - TYPE O
- QUICK UNION - TYPE B
- BLANKING CAP & PLUG - PUMP-IN SUB
- LUBRICATOR ACCESSORIES
- WIRELINE TOOL STRING
- Rope Socket
- S Wireline Stem - LS Lead Filled Stem
- 'SM' Roller Stem - 'MJ' Spang Link Jars - Mechanical Jars
- 'TJ' Wireline Tubular Jar - 'HJ' Hydraulic Jar
- 'SPJ' Spring Jar - 'WA' Wireline Accelerator
- 'SH' Shock Absorber - 'KJ' Knuckle Joints
- 'KJA' Knuckle Jar - 'QC' Quick Lock Couplings
- 'TS' Tubing Swage - 'TC' Tubing Gauge Paraffin Cutter
- 'BB' Blind Box - 'TL' Tubing End Locator
- 'SB' Sample Bailer
- 'HB' Hydrostatic Bailer - 'SAB' Sand Pump Bailer
- 'WO' Wireline Overshot - 'ROS' Releasable Overshot
- 'WS' Wireline Spear - 'FC' Fluted Centralizer
- 'WFM' Wireline Fishing Magnet - 'MT' Magnetic Fishing
Tool - 'IB' Impression
- lock
- Pulling Tools (JD & JU Series)
- 'R' Pulling Tool
- 'S' Pulling Tool
- 'GS' Pulling Tool - 'GU' Shear Up Adapter
- 'PX' Running Tool - 'B' Shifting Tool
- Pinning Tool - Releasing Tool
- 'WC' Wireline Cutter - Wireline Snipper
- 'GD' Go-devil - 'RGD' Roller Go-devil
- 'TB' Tubing Broach - 'PS' Paraffin Scratchers
- 'WW' Wireline Wirefinder - 'WR' Wireline Retriever
- 'WG' Wireline Grab - Center Spear
- Bow Spring Centralizer - Anti Blow-up Tool
- Wireline Swivel Joint - Tubing Gauge Cutter Ring Set
- Sucker Rod Connection - Wrench Flats on Sucker Rod
- Quick Lock Connection
- 'WCR' Wireline Crossovers
- O Series Orifice Valves
- Wireline Retrievable Super Flow Orifice Valve
- Flow Characteristics of Super Flow Orifice Valve
- Differential Valve
- Dummy and Equalizing Valves
- PDK-1 Wireline Retrievable Dummy Valve
- Latches - TG, M, T2
- Latches - RK, BK-2, RM
- Side Pocket Mandrels
- Conventional Mandrels
- High Strength Conventional Mandrels
- Running Tools, Pulling Tools
- HD TP and HD-TP/HD-TMP Positioning Tools
- Surface Flow Controls Motor Valves - MV Series
- Surface Flow Controls Motor Valves - FCV Series
- Surface Flow Controls Motor Valves - WFC Series
- Surface Flow Controls Motor Valves - ACV Series
- Standing Valves and Seating Nipples
- Time Cycle Controllers with accessories
- 4501 (mechanical) Time Cycle Controllers
- API Tubing Table
- Fluid Weight Conversion Table
- Valve and Seat Specifications
- Gas Rate Through Chokes
- Temperature Correction Chart
- 'LW' Line Wiper
- Grease Injection Control Heads
- Lubricator Risers
- Blowout Preventers - Page 1 (2.5 - 4 inch parts)
- Blowout Preventers - Page 2 (4 - 6.38 inch parts)
- Landing Nipples and Lock Mandrels
- Slip Lock Assembly
- Surge Tool Assembly
- Tubing Pack-Off Anchor Assembly
- Measuring Line Stuffing Boxes