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______________________________________________________________ “spending hundreds and hundreds and hundreds of billions of dollars every year for oil, much of it from the Middle East, is just about the single stupidest thing that modern society could possibly do. It’s very difficult to think of anything more idiotic than that.” ~ R. James Woolsey, Jr., former Director of the CIA
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Reservoir Engineers
www.ReservoirEngineers.com
What is Reservoir Engineering?
Reservoir engineering
is a vital part of the petroleum engineering industry. Reservoir engineers
are responsible for identifying the size of an oil and/or natural gas reservoir, the oil and/or
natural gas reserves in the reservoir and how to optimize and maximize the economic
recovery of these energy resources.
Aspects of reservoir engineering include; applied mathematics, chemistry,
physics, economic modeling, enhanced oil recovery, heavy oil recovery, oil
recovery, reservoir geology, reservoir modeling, production forecasting, PVT analysis of reservoir
fluids, simulation modeling, steam injection, waterflooding, well testing, how liquids and vapor phases of crude oil, natural gas, and water in reservoirs
act and react and finally, methods for reducing greenhouse gas emissions.
It is the reservoir engineers that the financial and investment industry turn to
to provide accurate reserve estimates for use in financial reporting to the
state regulators such as the Railroad Commission in Texas, as well as the SEC and other regulatory
agencies.
What is Gas Gathering?
Gas Gathering systems are the physical facilities that accumulate and transport natural gas from a well to an acceptance point of a transportation pipeline are called a gas gathering system.
What are Midstream
Assets?
Midstream Assets include those assets and services that link the supply side of the value chain within the industry, to the demand side for for these energy commodities.
The Midstream Assets and the Midstream Oil and Gas sector is the bridge between the energy producers and the energy end-users and - therefore, can only be as strong as the weakest link or bridge within the midstream oil and gas sector.
Typical midstream assets include;
natural gas gathering
natural gas treating
natural gas processing
natural gas liquids
NGL fractionation
natural gas storage
natural gas transportation
natural gas pipelines
natural gas compression
terminalling and storage
oil transportation
vapor recovery units
What
is the "Midtream Oil and Gas"
sector?
The "midstream oil and gas" sector receives the oil and natural gas from the upstream oil and natural gas sector and provides initial gas processing, terminalling and storage, and transports the oil and natural gas and natural gas liquids for further natural gas treating and desulfurization "downstream." The natural gas may be processed or treated in the midstream sector through gas processing or natural gas treating facilities for producing pipeline quality gas for direct sale to a interstate or intrastate natural gas pipeline, and may bypass the downstream oil and natural gas sector entirely.
The downstream sector usually refers to crude oil refineries and the selling and distribution of natural gas and products derived from crude oil. These products include Liquefied Petroleum Gas or "LPG," gasoline, jet fuel, diesel fuel, and other fuel oils, as well as asphalt and petroleum coke.
What
is "Upstream Oil and Gas"?
The oil and natural gas industry is divided into three major segments:
Upstream
Midstream
Downstream
The
Upstream Oil and Gas
segment is a term that refers to the searching,
drilling and production of crude oil and natural gas. The Upstream
Oil and Gas segment is also known as the "exploration and production"
or "E&P" segment.
The Upstream
Oil and Gas segment includes; exploring for potential underground
(or underwater) oil and natural gas fields (or reservoirs), drilling of exploratory wells, and
operating/producing the oil
and natural gas wells that "pay" with crude oil and/or
natural gas
What
are Master
Limited Partnerships?
Master Limited Partnership (MLPs) are limited partnerships that are publicly traded on a securities exchange.
MLPs
combine the tax benefits of Limited Partnerships with the liquidity and
protection/oversight of a publicly traded security.
Master Limited Partnerships are limited by regulation to apply to specific businesses - most notably - natural resources, including; oil and natural gas extraction and transportation.
To
qualify for MLP status, a partnership must generate at least 90 percent of its
income from "qualifying" sources/resources. For many Master Limited
Partnerships, this includes activities related to the production, processing or
transportation of oil, natural gas and coal.
Master
Limited Partnerships pay their investors through Quarterly Required
Distributions or QRDs. The amount of the QRDs is stated in the contract between
the Limited Partners (the investors) and the General Partner (the managers).
Failure of the General Partner to pay the quarterly required distributions
constitutes a default of the MLP Agreement.
Due
to the stringent provisions on Master Limited Partnerships and the QRD, the
majority of all Master Limited Partnerships are pipeline businesses, and natural
gas companies engaged in the "midstream" oil and natural gas sector,
which generated a reliable and steady income from the oil and natural gas
sector.
Because
MLPs are a partnership, there is no corporate income tax at either the state or
federal level. The Limited Partners (investors) are able to record a pro-rated
share of the investment in the Master Limited Partnership's depreciation on
their personal income tax filings which further reduces their (that year's) tax
liabilities. This is the primary benefit of Master Limited Partnerships and
provides MLPs relatively inexpensive funding and capital costs.
In
most new Master Limited Partnerships, the General Partner starts out with a
small stake or position in the company - typically in the 2% to 5% range.
However, the MLP receives "incentive distributions" from the net
income after the Quarterly Required Distributions. As the incentive
distributions are normally paid in the form of increased equity claims this
allows the General Partner to attain an increasingly greater percentage of
ownership in the company over time.
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What is Natural Gas Storage?
There are periods of time in peak periods of natural gas use, that a natural gas company (pipeline or LDC) may not be able to keep up with these peak demand periods. Natural gas storage is a way to help provide for the natural gas reserves or natural gas supplies that are needed during these peak demand periods. Having strategically-located natural gas storage capabilities can assist natural gas pipelines or LDCs provide the natural gas supply when their customers demand.
America's need for natural gas continues to grow.
Recent governments studies conclude that demand for clean-burning natural gas has continued to rise. In the last 20 years, natural gas consumption has risen nearly 25%.
The Energy Information Administration (EIA) estimates there are over 2,100 Trillion cubic feet (Tcf) of "technically recoverable natural gas" reserves in the United States, as reported in the EIA's 2010 Annual Energy Outlook. In 2009, the United States used just over 22 Trillion cubic feet of natural gas, making the U.S. one of the global leaders in natural gas consumption. This means the U.S. has enough natural gas supply to last about 100 years.
With greater demand comes greater need to be able to store natural gas. In the past 20 years, natural gas storage has increased less than 5%. This creates a serious constraint that can impact our nation by failing to keep up with natural gas supply and demand. Existing natural gas storage facilities will not be able to keep up with the demand for natural gas during increasingly greater periods of increasing demand, which could cost all consumers of natural gas billions of dollars.
More
Natural Gas Storage is Needed
There is a critical need for new high-volume natural gas storage facilities to meet the escalating demand for natural gas which will provide predictability of natural gas supply and reduce or eliminate volatility of natural gas prices during peak periods. Natural gas storage "balance" the load - or supply and demand requirements of all natural gas consumers and provides the "cushion" needed for large supplies of natural gas to serve all consumers during periods of peak demand.
Natural gas storage can take place in a number of underground natural gas facilities. From the time the natural gas is produced, it may be stored temporarily in underground natural gas storage facilities that may be one or more of the following; depleted oil or natural gas fields/reservoirs, salt dome caverns/salt dome storage or former aquifers.
Most of the natural gas storage in the U.S. takes place in naturally-occurring natural gas or oil reservoirs that have been depleted through production. An underground gas storage facility must contain enough “base gas” or “cushion gas” that provides adequate pressure to re-produce and extract the natural gas.
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We represent an interested investment group making acquisitions of upstream and midstream assets, including;
If you are interested in selling your midstream oil and gas / upstream oil and gas property or natural gas assets (must be located in U.S.), send information by email to:
info(@)GasGathering.com
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More About Gas Gathering
Gas Gathering lines are small-diameter pipelines move natural gas from the wellhead to the natural gas processing plant or to an interconnection with a larger mainline pipeline. Transporting natural gas from the wellhead to the final customer involves several physical transfers of custody and multiple processing steps. A natural gas pipeline system begins at the natural gas producing well or field. Once the gas leaves the producing well, a gas gathering system directs the flow either to a natural gas processing plant or directly to the mainline transmission grid, depending upon the initial quality of the wellhead product.
The processing plant produces pipeline-quality natural gas. This gas is then transported by pipeline to consumers or is put into underground storage for future use. Storage helps to maintain pipeline system operational integrity and/or to meet customer requirements during peak-usage periods.
Transporting natural gas from wellhead to market involves a series of processes and an array of physical facilities. Among these are:
Gas Processing Plant – This operation extracts natural gas liquids and impurities from the natural gas stream.
Mainline Transmission Systems – These wide-diameter, long-distance pipelines transport natural gas from the producing area to market areas.
Market Hubs/Centers – Locations where pipelines intersect and flows are transferred.
Underground Storage Facilities – Natural gas is stored in depleted oil and gas reservoirs, aquifers, and salt caverns for future use.
Peak Shaving – System design methodology permitting a natural gas pipeline to meet short-term surges in customer demands with minimal infrastructure. Peaks can be handled by using gas from storage or by short-term line-packing.
The
Natural Gas Gathering System
A natural gas pipeline system begins at a natural gas producing well or field. In the producing area many of the pipeline systems are primarily involved in "gas gathering" operations. That is, a pipeline is connected to a producing well, converging with pipes from other wells where the natural gas stream may be subjected to an extraction process to remove water and other impurities if needed. Natural gas exiting the production field is usually referred to as "wet" natural gas if it still contain significant amounts of hydrocarbon liquids and contaminants.
Under certain conditions some or all of the natural gas produced at a well may be returned to the reservoir in cycling, repressuring, or conservation operations and/or vented and flared. At this stage it is a mixture of methane and other hydrocarbons, as well as some non-hydrocarbons, existing in the gaseous phase or in a solution with crude oil. The principal hydrocarbons normally contained in the natural gas mixture are methane, ethane, propane, butane, and pentane. Typical non-hydrocarbon gases that may be present in reservoir natural gas are water vapor, carbon dioxide, helium, hydrogen sulfide, and nitrogen.
In proximity to the well are facilities that produce what is referred to as "lease condensate", that is, a mixture consisting primarily of pentanes and heavier hydrocarbons which is recovered as a liquid from natural gas. Other natural gas liquids, such as butane and propane, are recovered at downstream natural gas processing plants or facilities
Once it leaves the producing area, a pipeline system directs flow either to a natural gas processing plant or directly to the mainline transmission grid. Non-associated natural gas, that is, natural gas that is not in contact with significant quantities of crude oil in the reservoir, is sometimes of pipeline quality after undergoing a decontamination process in the production area, and does not need to flow through a processing plant prior to entering the mainline transmission system.
The
Natural Gas Processing
Plant
The principal service provided by a natural gas processing plant to the natural gas mainline transmission network is that it produces pipeline quality natural gas. Natural gas mainline transmission systems are designed to operate within certain tolerances. Natural gas entering the system that is not within certain specific gravities, pressures, Btu content range, or water content level will cause operational problems, pipeline deterioration, or even cause pipeline rupture.
Natural gas processing plants are also facilities designed to recover natural gas liquids from a stream of natural gas that may or may not have passed through lease separators and/or field separation facilities. These facilities also control the quality of the natural gas to be marketed. Several types of natural gas processing plants, employing various techniques and technologies to extract contaminants and natural gas liquids, are used to produce pipeline quality "dry" gas. At many processing plants the primary objective is the production of dry gas (demethanizing). Any remaining natural gas liquids extraction stream is directed to a separate plant to undergo what is referred to as a "gas fractionation" process.
But a number of natural gas processing plants do include these gas fractionation plants where saturated hydrocarbons are removed from natural gas and separated into distinct parts, or "fractions," such as propane, butane, and ethane. Essentially, natural gas is methane, a colorless, odorless, flammable hydrocarbon gas (CH4). Also present in natural gas production, especially that in association with oil production, are a number of petroleum gases. They include (in addition to ethane, propane and butane) ethylene, propylene, butylene, isobutane, and isobutylene. They are derived from crude oil refining or natural gas fractionation and are liquefied through pressurization.
The
Transmission Grid and Compressor Stations
The natural gas mainline (transmission line) is a wide-diameter, often-times long-distance, portion of a natural gas pipeline system, excluding laterals, located between the gathering system (production area), natural gas processing plant, other receipt points, and the principal customer service area(s). The lateral, usually of smaller diameter, branches off the mainline natural gas pipeline to connect with or serve a specific customer or group of customers.
A natural gas mainline system will tend to be designed as either a grid or a trunkline system. The latter is usually a long-distance, wide-diameter pipeline system that generally links a major supply source with a market area or with a large pipeline/LDC serving a market area. Trunklines tend to have fewer receipt points (usually at the beginning of its route), fewer delivery points, interconnections with other pipelines, and associated lateral lines.
A grid type transmission system is usually characterized by a large number of laterals or branches from the mainline, which tend to form a network of integrated receipt, delivery and pipeline interconnections that operate in, and serve major market areas. In form, they are similar to a local distribution company (LDC) network configuration, but on a much larger scale.
Between the producing area, or supply source, and the market area, a number of compressor stations are located along the transmission system. These stations contain one or more compressor units whose purpose is to receive the transmission flow (which has decreased in pressure since the previous compressor station) at an intake point, increase the pressure and rate of flow, and thus, maintain the movement of natural gas along the pipeline.
Gas compressors are used on a natural gas mainline transmission system are usually rated at 1,000 horsepower or more and are of the centrifugal (turbine) or reciprocating (piston) type. The larger gas compression stations may have as many as 10-16 units with an overall horsepower rating of from 50,000 to 80,000 HP and a throughput capacity exceeding three billion cubic feet of natural gas per day. Most compressor units operate on natural gas (extracted from the pipeline flow); but in recent years, and mainly for environmental reasons, the use of electricity driven compressor units has been growing.
Many of the larger mainline transmission routes are what is generally referred to as "looped." Looping is when one pipeline is laid parallel to another and is often used as a way to increase capacity along a right-of-way beyond what is possible on one line, or an expansion of an existing pipeline(s). These lines are connected to move a larger flow along a single segment of the pipeline system. Some very large pipeline systems have 5 or 6 large diameter pipes laid along the same right-of-way. Looped pipes may extend the distance between compressor stations, where they can transfer part of their flow, or the looping may be limited to only a portion of the line between stations. In the latter case, the looping often serves as essentially a storage device, where natural gas can be line-packed as a way to increase deliveries to local customers during certain peak periods.
To address the potential for pipeline rupture, safety cutoff meters are installed along a mainline transmission system route. Devices located at strategic points are designed to detect a drop in pressure that would result from a downstream or upstream pipeline rupture and automatically stop the flow of natural gas beyond its location. Monitoring the pipeline as a whole are apparatus known as SCADA which means Supervisory Control and Data Acquisition. SCADA systems provide monitoring staff the ability to direct and control pipeline flows, maintaining pipeline integrity and pressures as natural gas is received and delivered along numerous points on the system, including flows into and out of storage facilities.
Natural
Gas Market Centers/Hubs
Natural gas market centers and hubs evolved, beginning in the late 1980s, as an outgrowth of natural gas market restructuring and the execution of a number of Federal Energy Regulatory Commission’s (FERC) Orders culminating in Order 636 issued in 1992. Order 636 mandated that interstate natural gas pipeline companies transform themselves from buyers and sellers of natural gas to strictly natural gas transporters. Market centers and hubs were developed to provide new natural gas shippers with many of the physical capabilities and administrative support services formally handled by the interstate pipeline company as “bundled” sales services.
Two key services offered by market centers/hubs are transportation between and interconnections with other pipelines and the physical coverage of short-term receipt/delivery balancing needs. Many of these centers also provide unique services that help expedite and improve the natural gas transportation process overall, such as Internet-based access to natural gas trading platforms and capacity release programs. Most also provide title transfer services between parties that buy, sell, or move their natural gas through the center.
As of the end of 2008, there were a total of 33 operational market centers in the United States (24) and Canada (9).
Underground
Storage Facilities
At the end of the mainline transmission system, and sometimes at its beginning and in between, underground natural gas storage and LNG (liquefied natural gas) facilities provide for inventory management, supply backup, and the access to natural gas to maintain the balance of the system. There are three principal types of underground storage sites used in the United States today: depleted reservoirs in oil and/or gas fields, aquifers, and salt cavern formations. In one or two cases mine caverns have been used. Two of the most important characteristics of an underground storage reservoir are the capability to hold natural gas for future use, and the rate at which natural gas inventory can be injected and withdrawn (its deliverability rate).
Most underground storage facilities, 327 out of 399 at the beginning of 2008, are depleted reservoirs, which are close to consumption centers and which were relatively easy to convert to storage service. In some areas, however, most notably the Midwestern United States, some natural aquifers have been converted to natural gas storage reservoirs. An aquifer is suitable for natural gas storage if the water-bearing sedimentary rock formation is overlaid with an impermeable cap rock. While the geology of aquifers is similar to that of depleted production fields, their use in natural gas storage usually requires more base (cushion) gas and greater monitoring of withdrawal and injection performance. Deliverability rates may be enhanced by the presence of an active water drive.
During the past 20 years, the number of salt cavern storage sites has grown significantly because of its rapid cycling (inventory turnover) capability coupled with its ability to respond to daily, even hourly, variations in customer needs. The large majority of salt cavern storage facilities have been developed in salt dome formations located in the Gulf Coast States. Salt caverns leached from bedded salt formations in Northeastern, Midwestern, and Western States have also been developed but the number has been limited due to a lack of suitable geology. Cavern construction is more costly than depleted field conversions when measured on the basis of dollars per thousand cubic feet of working gas capacity, but the ability to perform several withdrawal and injection cycles each year reduces the per-unit cost of each thousand cubic feet of natural gas injected and withdrawn.
Underground natural gas storage inventories provide suppliers with the means to meet peak customer requirements up to a point. Beyond that point the distribution system still must be capable of meeting customer short-term peaking and volatile swing demands that occur on a daily and even hourly basis. During periods of extreme usage, peaking facilities, as well as other sources of temporary storage, are relied upon to supplement system and underground storage supplies.
Peaking needs are met in several ways. Some underground storage sites are designed to provide peaking and peak shaving services, but most often LNG (liquefied natural gas) in storage and liquefied petroleum gas such as propane are vaporized and injected into the natural gas distribution system supply to meet instant requirements. Short-term linepacking is also used to meet anticipated surge requirements.
The use of peak shaving, as well as underground storage, is essentially a risk-management calculation, known as peak-shaving. The cost of installing these facilities is such that the incremental cost per unit is expensive. However, the cost of a service interruption, as well as the cost to an industrial customer in lost production, may be much higher. In the case of underground storage, a suitable site may not be locally available. The only other alternative might be to build or reserve the needed additional capacity on the pipeline network. Each alternative entails a cost.
A local natural gas distribution company (LDC) relies on supplemental supply sources (underground storage, LNG, and propane) and uses linepacking to "shave" as much of the difference between the total maximum user requirements (on a peak day or shorter period) and the baseload customer requirements (the normal or average) daily usage. Each unit "shaved" represents less demand charges (for reserving pipeline capacity on the trunklines between supply and market areas) that the LDC must pay. The objective is to maintain sufficient local underground natural gas storage capacity and have in place additional supply sources such as liquefied natural gas or "LNG" and propane air to meet large shifts in daily demand, thereby minimizing capacity reservation costs on the supplying pipeline.
Prior to FERC Order 636 in 1992, many interstate pipeline companies had a
completely integrated supply system that was capable of delivering natural gas
from the wellhead to the ultimate retail gas consumer. But, following Order 636,
which separated gathering, marketing, and transmission operations, many pipeline
companies reorganized and broke up this system into discrete parts and assigned
them to affiliated companies.
The facilities, functions, and services required for gathering, processing, and
transportation were placed in affiliated companies or were spun off or sold to
other companies. Since most gas prices were no longer regulated,
gas gathering
service charges became subject to market forces and were a function of
buyer/seller negotiation, isolated from the transmission charges imposed by the
pipeline transporter.
Gas
Gathering continued
The corporate reorganizations brought about under the influence of FERC Order 636 caused a shift in the jurisdictional entities regulating the various facilities and services. The Federal Energy Regulatory Commission (FERC) had once regulated the entire integrated interstate pipeline system, but after the reorganizations, FERC became the regulating entity for only the interstate pipeline transportation and processing facilities and services. The spun-off or affiliated gathering facilities and services generally fell under state jurisdiction or other Federal agencies, such as the Department of the Interior, but in some cases FERC maintained jurisdiction. Especially unclear, and still contested in 2004, is the jurisdictional status of some Gulf of Mexico gathering systems.
These cases involve FERC's reclassification of portions of a pipeline's system
operating on the Outer Continental Shelf (OCS) as non-jurisdictional gathering
facilities and FERC's determination that a pipeline company can transfer those
facilities to its non-jurisdictional gathering affiliate. The key consideration
in these, and similar onshore cases, is that FERC retains rate jurisdiction over
those reclassified facilities that the pipeline retains and thus may regulate
rates charged for transportation on the pipeline's own gathering facilities
performed in connection with jurisdictional transportation. Rates on
non-jurisdictional facilities are market based and not subject to FERC oversight
or review. Consequently, some shippers have raised complaints that rates on
non-jurisdictional facilities may exceed a reasonable rate by an undue degree.
As a result of FERC's decision in Order 636 to promote competition by requiring
interstate pipelines to "unbundle" their previously bundled sales and
transportation into separate services and to transport natural gas for all
qualified shippers, some such pipelines have sought to shed OCS facilities that
primarily perform a gathering function. Accordingly, those pipelines have asked
FERC to reclassify OCS facilities that were previously classified as
transportation, and to authorize "spin-downs" of OCS gathering
facilities to affiliates.
To differentiate jurisdictional transportation and non-jurisdictional gathering
for pipelines, FERC for many years has employed two principal tests. Under the
"behind-the-plant" test, facilities upstream of compressors and
processing plants (i.e., toward the wellhead where the gas comes out of the
ground) were presumptively gathering facilities, while facilities downstream of
the plants (i.e., toward the consumer) were presumptively transportation
facilities. For gas that requires no processing, FERC employed a
"central-point-in-the-field" test, under which lateral lines that
collect and transport gas from separate wells that then converge into a single
large line were classified as gathering facilities, while facilities downstream
of the collection point in a field were classified as transportation. Since
1983, FERC has subsumed those two tests into a "primary function" test
that focuses on a number of physical factors (e.g., length, diameter, and
configuration of a pipeline) and certain other criteria, to determine whether
facilities are primarily devoted to gathering or transportation. Under the
primary function measure, no one factor is determinative, nor do all factors
apply in every situation.
FERC developed its primary function test in the context of onshore gathering
patterns. For natural gas produced on the Outer Continental Shelf (OCS),
pipelines generally are configured differently and typically do not gather gas
at a local, centralized point within a field as they would onshore to prepare it
for traditional transportation. As stated in EP Operating Co. v. FERC (5th
Circuit, 1989), "Rather, on the OCS, relatively long lines are constructed
to carry the raw gas from offshore platforms where 'only the most rudimentary
separation and dehydration operations' are conducted, to the shore or a point
closer to shore, where it can be processed into 'pipeline quality' gas." It
also notes that pipelines on the OCS must construct large pipes to carry (often
over a 100 miles away) the raw gas from offshore rigs to the shore for
processing. In response to the practical and physical differences between
onshore and offshore pipeline configurations, FERC modified its primary function
test for the OCS to allow for the increasing length and diameter of OCS
gathering lines, and later announced that it would "presume facilities
located in deep water [over 200 feet] are primarily engaged in gathering or
production."
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What is an Amine Plant?
Amine plants, also known as "Amine Units" are used in "gas sweetening" in the midstream oil and gas sector for "gas processing" and "natural gas treating."
Amine plants provide H2S removal as well as CO2 removal from natural gas and liquid hydrocarbons. The process involves both absorption and chemical reactions.
What
is a "Cryogenic Plant"?
A cryogenic
plant is another term for a "gas
processing plant." Gas
processing plants produce natural
gas liquids products, including ethane, at very low or "cryogenic"
operating temperatures.
What
are Gas Compressors?
Gas compressors are mechanical device that increase the pressure of a gas by reducing its volume. Gas compressors are responsible for moving the natural gas from the oil or natural gas production well to homes and businesses via natural gas pipelines and gas compression stations.
Gas compression also increases the temperature of the gas during compression.
What
is Gas Processing?
Natural Gas Processing plants separate the various hydrocarbons and natural gas liquids from the pure natural gas (methane or CH4) to produce what is known as 'pipeline quality' natural gas. Natural gas pipeline companies have requirements on natural gas they buy from producers which is why the natural gas processing plants are located where they are, and why they separate the ethane, propane, butane, and pentanes from the methane. Natural gas liquids or NGLs include ethane, propane, butane, iso-butane, and natural gasoline.
What
is Gas
Sweetening?
Sulfur
exists in natural gas and is known as hydrogen sulfide (H2S). Natural gas
is usually considered "sour" if hydrogen sulfides content exceeds
5.7 milligrams of H2S per cubic meter of natural gas. The process
hydrogen sulfide removal from sour gas is commonly referred to as "gas
sweetening."
The primary process for gas sweetening
- or turning
sour natural gas to
sweet natural gas - is similar to the
processes of
glycol dehydration
and NGL absorption. In this case, however, amine
solutions are used to remove the hydrogen sulfide (H2S) through
amine plants. This process is known simply
as the 'amine process', or alternatively as the Girdler process, and is used in
95 percent of U.S. gas sweetening
operations. The sour gas is run through a
tower, which contains the amine solution. This solution has an affinity for
sulfur, and absorbs it much like glycol absorbing water. There are two principle
amine solutions used, monoethanolamine (MEA) and diethanolamine (DEA). Either of
these compounds, in liquid form, will absorb sulfur compounds from natural gas
as it passes through. The effluent gas is virtually free of sulfur compounds,
and thus loses its sour gas status. Like the process for NGL extraction and
glycol dehydration, the amine solution used can be regenerated (that is, the
absorbed sulfur is removed), allowing it to be reused to treat more sour gas.
Although most sour gas sweetening
involves the amine absorption process, it is
also possible to use solid desiccants like iron sponges to remove the sulfide
and carbon dioxide.
Sulfur can be sold and used if reduced to its elemental form. Elemental sulfur
is a bright yellow powder like material, and can often be seen in large piles
near gas treatment plants, as is shown. In order to recover elemental sulfur
from the gas processing plant, the sulfur containing discharge from a gas
sweetening process must be further treated. The process used to recover sulfur
is known as the Claus process, and involves using thermal and catalytic
reactions to extract the elemental sulfur from the hydrogen sulfide solution.
Some of the above information from www.NaturalGas.org with our thanks.
What is Glycol Dehydration?
Glycol dehydration is used in the production and processing of natural gas by using a liquid desiccant that removes water from natural gas and natural gas liquids (NGL).
Various types of glycols are used in this process including;
triethylene glycol (TEG)
diethylene glycol (DEG)
ethylene glycol (MEG)
tetraethylene glycol (TREG).
TEG is the most commonly used glycol in the natural gas industry.
What is H2S
Removal?
H2S,
or Hydrogen Sulfide, is a hazardous and corrosive element found in oil and
natural gas which needs to be removed from the hydrocarbon before the oil or
natural gas can be sold. The hydrogen
sulfides are usually removed in a mid-stream gas processing facility by
either iron sponges or amine plants.
What
is a Heater Treater?
A "Heater
Treater" is used in the oil and gas production process and is used to
removes water and gas from the produced oil - and to improve its quality for
sale into a crude oil pipeline or for other transport. A heater
treater typically combines the following components inside the heater
treater: a heater, free-water knockout, and oil and gas separator.
What is Natural
Gas Treating?
As natural gas is produced from either a natural gas well, or from an oilwell which contains "associated gas," the natural gas must be treated or processed before it can be used at a home or business as a fuel.
Natural gas treating or natural gas processing, takes place at gas processing plants to remove the impurities and other hydrocarbons other than the methane itself, or CH4.
The by-products and impurities of natural gas that must be treated or processed include; ethane, propane, butane, isobutane, pentane, isopentane and higher molecular weight hydrocarbons, as well as H2S or elemental sulfur, carbon dioxide (CO2), water vapor and sometimes helium and nitrogen.
What is "NGL Fractionation"?
NGL, or natural gas liquids fractionation plants purpose is to separate the mixed natural gas liquids stream into separated products. These natural gas liquids that are separated by heat at NGL Fractionation plants include; ethane, propane, normal butane, isobutane and natural gasoline.
Gas Gathering
www.GasGathering.com
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_______________________________________________________
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Energy
Independence
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Decentralized
Energy
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Energy
Plan for America
www.EnergyPlanForAmerica.com
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Foreign Oil!
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______________________________________________________
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EOR Technologies is a new company that seeks to expand the use Enhanced Oil Recovery technologies in the U.S. and to end our dependence on foreign fossil fuels.
EOR Technologies represents a significant opportunity for oil and natural gas well owners and operators to significantly increase their oil production and revenues through our range of EOR technologies and services.
With the recent plunge in oil prices, our principal investor is now "on the sidelines" and we are seeking a new strategic partner/investor and provider of "turnkey" EOR services.
In the U.S., Enhanced Oil Recovery represents a $24 Trillion market opportunity according to the U.S. The Department of Energy. The $24 Trillion figure is based on oil at $100/bbl. The DOE's studies and reports indicate that the U.S. can recover 240 billion barrels of oil through Enhanced Oil Recovery.
Monty Goodell, Chairman of the Renewable Energy Institute, states, "Enhanced Oil Recovery is the 'bridge' we need that provides us the time to transition to home-grown renewable energy and away from fossil fuels. Enhanced Oil Recovery resolves several critical and strategic problems facing our country. First of all, we still need fossil fuel - here in the U.S., we have 240 billion barrels of oil we could recover with Enhanced Oil Recovery technologies according to the Department of Energy. With oil at $80/barrel, we send over $1 Billion overseas EVERY day to import the oil we need. By deploying EOR Technologies here in the U.S., we create jobs here instead of in Saudi Arabia, Venezuela, Russia and China, and produce our own energy for our own consumption. If we started recovering the 'stranded oil' from our own oil wells, we would never again need to import another drop of oil from overseas, saving almost $400 billion every year, and creating new jobs. Enhanced Oil Recovery provides us the time and the bridge, to a more sustainable energy future."
"And, there are environmental benefits and dividends as well," Mr. Goodell adds, "as Enhanced Oil Recovery can remove billions of tons of Carbon Dioxide Emissions from the atmosphere each year. CO2 is used in Enhanced Oil Recovery to recover the stranded oil and then sequesters the CO2 in oil & gas reservoirs after the stranded oil has been produced. Through CO2 Injection, the "stranded oil and gas" that would not have otherwise been recovered, is left behind in the oilwell, "sequestered" permanently" according to Mr. Goodell.
We are committed to reducing and eliminating greenhouse gas emissions and carbon dioxide emissions through our sustainable power and energy operations.
In association with the Renewable Energy Institute, affiliate companies and investors, we provide "turnkey" Renewable Energy Project development services that range from initial Engineering Feasibility & Economic Analysis Studies through "turnkey" project development, including construction/installation, start-up and commissioning, Operations & Maintenance, and Long Term Service Agreements for the lifetime of our power plants and energy systems.
EOR Technologies include:
Carbon
Capture and Sequestration
www.CarbonCaptureAndSequestration.com
CO2 - EOR
www.CO2-EOR.com
CO2 Flooding
www.CO2Flooding.com
CO2 Injection
www.CO2Injection.com
Enhanced Oil Recovery
www.EnhancedOilRecovery.com
EOR Technologies
www.EORtechnologies.com
Microbial EOR
www.MicrobialEOR.com
Nitrogen Injection
www.NitrogenInjection.com
Radial
Jet Enhancement
www.RadialJetEnhancement.com
Stranded Gas
www.StrandedGas.com
Stranded
Oil
www.StrandedOil.com
Stranded Oil and Gas
www.StrandedOilAndGas.com
Steam Injection
www.SteamInjection.com
Steam Assisted Gravity Drainage
www.SteamAssistedGravityDrainage.com
Toe to Heel Air Injection
www.ToeToHeelAirInjection.com
For more information about EOR Technologies,
call/email:
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We
Support American Energy Independence,
and the "Greening" of America's Power and Energy Infrastructure
Through Renewable
Energy Technologies
This Will Not Happen Overnight - and Requires a Transition
Period from Fossil Fuels to a Renewable and Sustainable
Power and Energy Economy.
We
Believe that Enhanced Oil
Recovery is that "Bridge"
to the Future and that Enhanced
Oil Recovery
will be the Technology that Makes America Energy Independent
and Employs Hundreds of Thousands of Americans
Recovering America's Oil.
America
Needs to Produce America's Oil,
Without Being Dependent on
China, Saudi Arabia, Venezuela, Russia or OPEC
for our energy requirements!
Never
Again, Will America Be Held Hostage to Oil Sheiks,
OPEC and
From Countries that Don't Like Us.
America
Needs America's Oil!
www.AmericaNeedsAmericasOil.com
Drill
Baby Drill!
www.DrillBabyDrill.com
Reservoir
Engineers
www.ReservoirEngineers.com
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