Purification of gas with liquid ionic compounds

Gas separation: processes – Selective diffusion of gases – Selective diffusion of gases through substantially solid...

Reexamination Certificate

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C095S052000, C095S231000, C095S236000, C095S237000

Reexamination Certificate

active

06579343

ABSTRACT:

FIELD OF THE INVENTION
This invention pertains to the purification or separation of gases using liquid ionic compounds.
BACKGROUND AND SUMMARY OF THE INVENTION
Purified gases are necessary for many industrial processes. For example, air must be purified by removing water vapor to produce dried air for use in machinery such as spray painting equipment, dental compressors, coordinate measuring machines, process controls, HVAC systems, pneumatic controls, electronics, and the like. Furthermore, dried air is required for the preparation of dry nitrogen. Purified nitrogen, free of both water and oxygen, is used in the storage and shipping of both flowers and food, as well as in delicate scientific operations, such as gas chromatography and mass spectroscopy. Other important industrial gases that are used in purified form include helium, argon, hydrogen, oxygen, and hydrocarbons. Typically, the gas purification processes involve the removal of water, carbon dioxide, or other component gases which may interfere with the end-use dependent application of the purified gas.
The natural gas commonly used in nearly every household originates in underground sedimentary rock formations. Natural gas may contain a variety of impurities including carbon dioxide (CO
2
) and water. It is desirable to remove these two impurities for several reasons. Water may form hydrocarbon hydrates, possibly forming solids, that can plug pipelines and pumping equipment. These hydrates are an exceptional concern in cold climates or in high-pressure systems where solid formation may be more likely. In addition, the presence of CO
2
tends to decrease the heating value of natural gas. Finally, the combination of CO
2
and water impurities in natural gas may form carbonic acid which is corrosive to pumping equipment and the pipeline used for transporting the natural gas to storage facilities or end-users. Economic benefit is realized by removing these impurities, and by doing so as close to the well-head as possible.
Current methods of gas purification include the use of serial gas/liquid absorbers or gas/solid adsorbers. Gas/liquid absorbers may include pure liquids or liquid solutions that preferentially partition components of the gas. Gas/solid adsorbers may include substances, such as sodium bicarbonate, and the like, that preferentially remove certain compounds based upon affinity, or molecular sieves that differentiate the various gas components on the basis of molecular size or other physical property. The liquid or solid material employed in these separators is known as a mass separating agent (MSA) and advantageously exhibits a differential affinity for one or more of the gas components. MSAs may also be chosen, for example based on their stability to extreme environments, such as extremes in temperature or pressure, stability to certain organic solvents, and stability to pH extremes. Furthermore, MSAs may be added directly to a process stream to enable separation.
Other separation schemes may also be employed, such as the use of inorganic membranes, polymeric membranes, supported liquid membranes, and the like. Gases may also be separated in cryogenic processes.
Serial gas/liquid and gas/solid separators may be configured in linear arrays of absorption and adsorption units. These arrays are designed to remove a plurality of gaseous impurities by contacting a gas stream with several liquid or solid MSAs, each designed to remove preferentially at least a portion of these gaseous impurities, thereby producing an effluent gas stream enriched in the remaining gaseous components. In such processes, the liquid or solid MSA becomes loaded with the gaseous impurity. In an alternative arrangement, the liquid or solid MSA may preferentially take up the desired gas component for recovery later, thus producing an effluent gaseous stream of impurities. The desired component may be released from the MSA in another step of the process. It is appreciated that the process design selected for removal of impurities or the alternative collection of a desired component in a given gas purification procedure will depend upon several factors, including the selectivity exhibited by the MSA for particular gas components, the ease with which the desired component may be recovered from the MSA, and others.
In systems where impurities are removed by selective absorption, it is often the case that multiple absorbers are used, one for each gas component impurity. For example, at present, two absorbers are required to remove CO
2
and water from natural gas. Carbon dioxide can be selectively removed with a gas/liquid absorption unit charged with an aqueous amine solution, such as mono- or diethanolamine. These amines form carbamates upon reaction with CO
2
, and these carbamates preferentially partition into the aqueous liquid stream. Similarly, water may be removed by preferential absorption with a gas/liquid absorption unit charged with an ethylene glycol liquid stream. In addition, water may be preferentially removed with polymeric membrane modules.
As many gas purification processes require the removal of more than one impurity, current conventional gas/liquid absorbers employ a separate absorption unit for removing each impurity. For example, one unit designed to remove carbon dioxide and an additional unit designed to remove water may be used as described above for natural gas. In addition, volatile components present in the absorbers, such as the amines used for CO
2
absorption, often evaporate into the gas stream. Thus, the removed CO
2
impurity may be replaced by the amine absorbing component. The resulting amine contamination is typically removed via condensation by means of a cold trap, and may be returned to the absorbing unit. However, such removal requires additional components added to the purification system. The requirement for multiple absorption units along with additional purification steps to remove subsequently released MSA can increase process time and operating costs. Furthermore, such complex systems may preclude near well-head implementation in deference to a centralized system for purification, and further increase the overall cost of goods resulting from the increased cost of transporting impure material. Finally, once exhausted, traditional absorbers must be replaced and few options are available for recovery or regeneration of spent MSAs, thereby adding replacement and disposal costs.
Liquid ionic compounds (LICs), often called “ionic liquids” are essentially non-volatile, having immeasurably low vapor pressures; they are not volatilized into the purified gas stream. Their low vapor pressure minimizes loss of absorbing material during use and provides a simple mechanism for regeneration, such as by distillation, evacuation, or by extraction with a supercritical fluid, such as supercritical carbon dioxide.
As described herein, in one embodiment, the LIC selectively solubilizes impurities, leaving the desired gas in the gas stream. It is appreciated that in variations of the methods described herein, the LIC may selectively solubilize the desired gas component, leaving the impurities behind in the effluent stream. In such variations, recovery of the desired material may be accomplished by processes analogous to the regeneration mechanisms described above. Distillation, evacuation, or extraction with a supercritical fluid, and the like, will regenerate the LIC and simultaneously recover the desired purified gas; recovery rates greater than 90% are not unexpected.
Moreover, LICs can be tailored for specific needs, allowing a single absorption unit to be used for the removal of more than one impurity, depending on the relative solubilities and/or diffusibilities in the LIC of the desired gas and the impurities.
Furthermore, LICs may be prepared by simple and relatively inexpensive methods. Therefore, purification systems designed around LICs may be more amenable to near-wellhead processes in anticipation of their reduced operating costs. Finally, their exceedingly low vapor pressures make LICs environmentally

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