Patent Grant
9441170
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/560,653 filed Nov. 16, 2011, which is expressly incorporated herein by reference.
The present disclosure relates to a process for removing nitrogen, sulfur, heavy metals, and acid protons from sulfur-, nitrogen-, and metal-bearing shale oil, bitumen, heavy oil and petroleum refinery streams so that these materials may be used as a hydrocarbon fuel. More specifically, the present disclosure relates to removing nitrogen, sulfur, heavy metals and acid protons from shale oil, bitumen, heavy oil, or petroleum refinery streams while at the same time, upgrading these materials to have a higher hydrogen-to-carbon ratio.
U.S. patent application Ser. No. 12/916,984 (which has been incorporated herein by reference) has been published as United States Patent Application Publication No. 2011/0100874. The reader is presumed to be familiar with the disclosure of this published application. This published application will be referred to herein as the “874 application.”
The demand for energy (and the hydrocarbons from which that energy is derived) is continually rising. However, hydrocarbon raw materials used to provide this energy often contain difficult-to-remove sulfur and metals. For example, sulfur can cause air pollution and can poison catalysts designed to remove hydrocarbons and nitrogen oxide from motor vehicle exhaust, necessitating the need for expensive processes used to remove the sulfur from the hydrocarbon raw materials before it is allowed to be used as a fuel. Further, metals (such as heavy metals) are often found in the hydrocarbon raw materials. These heavy metals can poison catalysts that are typically utilized to remove the sulfur from hydrocarbons. To remove these metals, further processing of the hydrocarbons is required, thereby further increasing expenses.
Currently, there is an on-going search for new energy sources in order to reduce the United States' dependence on foreign oil. It has been hypothesized that extensive reserves of shale oil, which constitutes oil retorted from oil shale minerals, will play an increasingly significant role in meeting this country's future energy needs. In the U.S., over 1 trillion barrels of usable, reserve shale oil are found in a relatively small area known as the Green River Formation located in Colorado, Utah, and Wyoming. As the price of crude oil rises, these shale oil resources become more attractive as an alternative energy source. In order to utilize this resource, specific technical issues must be solved in order to allow such shale oil reserves to be used, in a cost effective manner, as hydrocarbon fuel. One issue associated with these materials is that they contain a relatively high level of nitrogen, sulfur and metals, which must be removed in order to allow this shale oil to function properly as a hydrocarbon fuel.
Other examples of potential hydrocarbon fuels that likewise require a removal of sulfur, nitrogen, or heavy metals are bitumen (which exists in ample quantities in Alberta, Canada) and heavy oils (such as are found in Venezuela).
The high level of nitrogen, sulfur, and heavy metals in shale oil, bitumen and heavy oil (which may collectively or individually be referred to as “oil feedstock”) makes processing these materials difficult. Typically, these oil feedstock materials are refined to remove the sulfur, nitrogen and heavy metals through a process known as “hydro-treating.”
Hydro-treating may be performed by treating the material with hydrogen gas at an elevated temperature and an elevated pressure using catalysts such as Co—Mo/Al2O3 or Ni—Mo/Al2O3.
In the present invention, the oil feedstock is mixed with an alkali metal (such as sodium) and hydrogen gas. This mixture is reacted under modest pressure (and usually at an elevated temperature). The sulfur and nitrogen atoms are chemically bonded to carbon atoms in the oil feedstocks. The sulfur and nitrogen heteroatoms are reduced by the alkali metals to form ionic salts (such as Na2S, Na3N, Li2S, etc.). To prevent coking (e.g., a formation of a coal-like product), the reaction occurs in the presence of hydrogen gas that can form bonds with the carbon atoms of the oil feedstock previously bonded to the heteroatoms. The hydrogen atom bonds to the carbon atoms that were previously bonded to the heteroatoms, thereby increasing the hydrogen-to-carbon ratio of the oil feedstock and decreasing the heteroatom to carbon ratio of the resulting organic feedstock. After the hydro-treating reaction, the organic phase (oil feedstock) is less viscous and may be sent for further refining into a hydrocarbon fuel material.
The ionic salts formed in the hydro-treating process may be removed from the organic products by filtering, or first mixing the treated feedstock with hydrogen sulfide to form an alkali hydrosulfide, which forms a separate phase from the organic phase (oil feedstock). This reaction is shown below with sodium (Na) being the alkali metal, although other alkali metals may also be used:
Na2S+H2S→2NaHS (which is a liquid at 375° C.)
Na3N+3H2S→3NaHS+NH3
The nitrogen product is removed in the form of ammonia gas (NH3) which may be vented and recovered, whereas the sulfur product is removed in the form of an alkali hydro sulfide, NaHS, which is separated for further processing. Any heavy metals will also be separated out from the organic hydrocarbons by gravimetric separation techniques.
As part of the process, alkali metals are used. An advantage of using alkali metals such as sodium or lithium instead of hydrogen to reduce the heteroatoms is alkali metals offer a greater reduction strength. In other words, the alkali metals are better able to reduce the heteroatoms and form alkali metal nitrides or alkali metal sulfides. Further, by using alkali metals, there is less need to saturate rings with hydrogen to destabilize them so that the heteroatoms can be reduced, making it possible to remove heteroatoms with significantly less hydrogen.
It should be noted that the alkali metal treatment process is known in the industry and is described, for example, in U.S. Pat. No. 3,787,315, U.S. Patent Application Publication No. 2009/0134040 and U.S. Patent Application Publication No. 2005/0161340. (These documents are expressly incorporated herein by reference.)
A disadvantage of using the hydro-treating process is that hydrogen gas is a necessary reactant needed for the hydro-treating process. However, hydrogen gas can be expensive. Typically, hydrogen gas is formed by reacting hydrocarbon molecules with water. For example, in the United States, 95% of the hydrogen is formed using the Steam-Methane Reforming Process from natural gas. In the first step known as the reforming step, methane (CH4) in natural gas is reacted with steam (H2O) at 750° C.-800° C. to produce synthesis gas (syngas). Syngas is a mixture primarily comprised of hydrogen gas (H2) and carbon monoxide (CO). In the next step, known as the water gas shift reaction, the carbon monoxide produced in the first reaction is reacted with steam (H2O) over a catalyst to form hydrogen gas (H2) and carbon dioxide (CO2). This second process (e.g., the water gas shift reaction) occurs in two stages: the first stage occurring around 350° C. and the second stage occurring at about 200° C.
The overall reaction for the Steam-Methane Reforming Process is as follows:
CH4+2H2O→4H2+CO2
Thus for every (theoretical) mole of hydrogen gas produced, 0.25 moles methane and 0.5 moles of water are required. Also, for every mole of hydrogen gas produced, 0.25 moles of carbon dioxide are produced and released to the atmosphere. It should be noted that the Steam-Methane Reforming Process is typically only 65-75% efficient. Thus at 70% efficiency, the Steam-Methane Reforming Process will actually utilizes 0.36 moles of methane and 0.71 moles of water while releasing 0.36 moles of carbon dioxide for every mole of hydrogen produced.
This production of carbon dioxide during the hydro-treating process is considered problematic by many environmentalists due to rising concern over carbon dioxide emissions and the impact such emissions may have on the environment.
An additional problem in many regions is the scarcity of water resources. For example, in the region of Western Colorado and Eastern Utah where parts of the Green River Formation of shale oil is located, the climate is arid and the use of water in forming hydrogen gas can be expensive.
Alternatively, some industrialists have used an electrolysis process to provide the hydrogen gas supply needed for their hydro-treating process. This electrolysis reaction involves the electrolytic decomposition of water. In this electrolytic reaction, water is split to form hydrogen at a cathode and oxygen at an anode:
H2O→H2+1/2)2
In this reaction, electrical energy is used to split the water. If the cell runs at 90% efficiency and runs at about 1.4 Volts, then the electrical energy required is about 72 kcal per mole of created hydrogen. For every mole of hydrogen produced in this electrolysis reaction, one mole of water is consumed. Because one mole of water is consumed to produce hydrogen in this method, more water is required to produce the hydrogen gas via electrolysis than is required to produce the hydrogen using the Steam-Methane Reforming Process (which requires 0.71 moles water). Thus, in arid climates where the cost of water is high, using an electrolysis process to produce hydrogen may not be economically feasible.
While conventional hydro-treating processes are known, they are expensive and require large capital investments in order to obtain a functioning hydro-treating plant. There is a need in the industry for a new process that may be used to remove heteroatoms such as sulfur and nitrogen from oil feedstocks, but that is less expensive than hydro-treating. Such a process is disclosed herein.
Additionally, naphthenic acids must be removed from many organic streams that are produced by refineries. Naphthenic acids (“NAPs”) are carboxylic acids present in petroleum crude or various refinery streams. These acids are responsible for corrosion in refineries. A common measure of acidity of petroleum is called the Total Acid Number (“TAN”) value and is defined as the milligrams (mg) of potassium hydroxide needed to neutralize the acid in one gram of the petroleum material. (Other acids found in the oil feedstock may also contribute to the TAN value). All petroleum streams with TAN >1 are called high TAN. NAPs are a mixture of many different compounds and cannot be separated via distillation. Moreover high TAN crudes are discounted over Brent Crude prices. For example, Doba crude with a TAN of 4.7 is discounted by $19 per barrel on a base price of $80 for Brent crude.
NAPs boil in the same range as that of kerosene/jet fuel. (However, kerosene/jet fuels have very stringent TAN specifications.) Attempting to neutralize these acids using aqueous caustic or other bases form salts. These salts in presence of water, lead to formation of stable emulsions. Additional methodologies of NAP reduction include hydrotreating or decarboxylation that are both destructive methodologies and the NAPs cannot be recovered using these methods. Solvent extraction or adsorption methodologies lead to high costs and energy usage for sorbent regeneration or solvent boiling. A new method for NAPs removal with lower energy consumption wherein NAPs can be recovered and processed as commercial products is required. Accordingly, a new method of neutralizing and/or removing NAPs is needed. Such a method and device is disclosed herein.
The present embodiments include a method of upgrading an oil feedstock with the benefit of a strong alkali metal agent without directly being required to handle, store, or transport the alkali metal. The method comprises obtaining a quantity of an oil feedstock, the oil feedstock comprising at least one carbon atom and a heteroatom and/or one or more heavy metals. The quantity of the oil feedstock is reacted with an alkali metal generated on an electrode within the reactor. The reaction with the alkali metal may also include using an upgradant hydrocarbon such as hydrogen gas or a hydrocarbon.
In order to implement these embodiments, a reactor may be utilized with at least two chambers separated in part by a membrane conductive to alkali metal ions. This membrane conducts alkali metal ions from an alkali metal ion source material (such as a liquid comprised of sodium salts or sodium metal). A positive charged electrode (anode) is in communication with the alkali metal ion source. The opposite chamber of the reactor (called the feedstock chamber) includes a feedstock stream (comprised of the organic oil feedstock) and a negatively charged electrode (cathode). The alkali metal enters the feedstock chamber and reacts with the heteroatom and/or the heavy metals in the feedstock to form one or more inorganic products, wherein the upgradant hydrocarbon reacts with the oil feedstock to produce an upgraded oil feedstock. The reaction with the upgradent hydrocarbon operates such that the number of carbon atoms in the upgraded oil feedstock may be greater than the number of carbon atoms in the original oil feedstock. The inorganic products are then separated from the upgraded oil feedstock. (The reaction of the oil feedstock, the alkali metal, and the upgradant hydrocarbon molecule may be implemented with or without using hydrogen gas. If hydrogen gas is utilized, the amount of hydrogen gas needed is much less than would be required using conventional hydrotreating.)
In some embodiments, the alkali metal comprises sodium, lithium, or alloys of lithium and sodium. The upgradant hydrogen source may comprise hydrogen, natural gas, shale gas and/or mixtures thereof. In other embodiments, the upgradant hydrocarbon comprises methane, ethane, propane, butane, pentane, their isomers, ethene, propene, butene, pentene, dienes, and/or mixtures thereof. (Oil retort gas, which is a mixture of gases that is produced in a refinery process may also be used as the upgradant hydrocarbon.)
The process of reacting the feedstock with the alkali metal may consist of two steps. A first step involves having alkali metal ions be transferred across the membrane and reduced to metal at the membrane surface at a negatively charged electrode (which may be directly fixed to the membrane surface). A second step involves having the formed alkali metal react directly with the constituents in the oil feedstock (or carried away with the oil to react downstream). The electrode where the alkali metal is formed may be porous, or comprised of a mesh. In another embodiment, the electrode may be a film of metallic alkali metal connected to an electrical lead (or current collector). To maintain continuity, a screen or mesh may provide a divider to separate a zone where the alkali metal is reduced from the oil feedstock. This screen allows the alkali metal to pass through as it is formed.
The reaction between the alkali metal and the oil feedstock may occur at a pressure that is between barometric and about 2500 psi and/or at a temperature that is between about 100° C. temperature and 450° C. In other embodiments, the reaction between the alkali metal and the oil feedstock occurs at a temperature that is above the melting point of the alkali metal but is lower than 450° C. Further embodiments may utilize a catalyst in the reaction. The catalyst may comprise molybdenum, nickel, cobalt or alloys thereof, molybdenum oxide, nickel oxide or cobalt oxides and/or combinations thereof.
As the reaction between the alkali metal and the oil feedstock produces inorganic products, a separation step may be needed. The separation used in the process may occur in a separator, wherein the inorganic products form a phase that is separable from an organic phase that comprises the upgraded oil feedstock and/or unreacted oil feedstock. To facilitate this separation, a flux may be added to the separator. After separation, the alkali metal from the inorganic products may be regenerated and reused.
The upgraded oil feedstock produced in the reaction may have a greater hydrogen-to-carbon ratio than the oil feedstock. The upgraded oil feedstock produced in the reaction may also have a greater energy value than the oil feedstock. Further, the heteroatom-to-carbon ratio of the upgraded oil feedstock may be less than the heteroatom-to-carbon ratio of the oil feedstock.
Additional embodiments may be designed in which an alkali metal is added to the oil feedstock in order to reduce the TAN value of the oil feedstock. Specifically, the alkali metal may react with the oil feedstock to remove the acidic components, thereby lowering the TAN value. In some embodiments, the original (unreacted) oil feedstock may have a TAN value of greater than or equal to 1, but after reaction with the alkali metal, may have a TAN value of less than or equal to 1.
The present embodiments relate to a method to de-acidify feedstocks and refinery streams. Such de-acidification is beneficial as it may operate to reduce piping corrosion and may convert naphthenic acids to a salt form. The present embodiments involve the addition of alkali metals (such as sodium or lithium metal) to the feedstocks as a means of reacting with the naphthenic acids, thereby de-acidifying these acids. When this reaction occurs, the naphthenic acids may be converted into the corresponding sodium or lithium salts (or other inorganic products). Hydrogen gas is also formed in this reaction. This reaction is summarized as follows:
R—COOH+Na→(R—COO−)Na++1/2 H2
Alternatively, the sodium may further react with oxygen atoms to eliminate the carboxyl group as shown in the following formula:
R—COOH+4Na+H2→R—CH3+2Na2O
The reaction with NAPs in this manner may be desirable and may result in a reduction of Total Acid Number (“TAN”) associated with the oil feedstock. There are multiple different ways in which the alkali metal may be added to the feedstock. In one embodiment, the sodium or lithium metal is directly added to the stream. Once this occurs, the inorganic products may then be filtered from the oil stream. Other embodiments may also be designed (as described herein) to provide other mechanisms for adding the alkali metal to the stream of oil feedstock (such as, for example, by forming the alkali metal in situ).
It should be noted that, in addition to reacting with the acids (such as naphthenic acids), the alkali metals that are added to the feedstock may also react to remove sulfur, nitrogen, metals (such as heavy metals), etc. This process for removing these metals/heteroatoms is discussed in the '874 application. Thus, by adding alkali metals to the oil feedstock, the problems associated with metals/heteroatoms in the stream, as well as problems with acids in the stream, may be overcome.
It should be noted that many in the oil processing industry are uncomfortable handling metallic sodium or lithium because of its reactive nature. In other words, these practitioners are uncomfortable using sodium/lithium and are uncomfortable adding these reagents directly to their oil feedstock streams. Accordingly, the present embodiments also provide methods and devices which operate to electrochemically produce alkali metals within an oil feedstock chamber (e.g., in situ), thereby bringing an alkali metal such as sodium in direct contact with the feedstock. Once this alkali metal is produced in the chamber, it is consumed by reacting with the heavy metals/heteroatoms and/or the acids in the feedstock. These embodiments may be desirable in that they provide the strong reducing power and reactivity associated with alkali metals without ever having an appreciable amount of the metal present. In other words, the present embodiments upgrade an oil feedstock using the alkali metal (e.g., a strong agent) without the practitioner being required to handle, store, or transport the alkali metal.
Referring now to
The oil feedstock 9 comprises a quantity of naphthenic acids 8. As described above, naphthenic acids 8 comprise carboxylic acids present in petroleum crude or various refinery streams. Naphthenic acids 8 are a mixture of many different compounds and cannot be separated out via distillation. In order to eliminate the naphthenic acids 8 from the oil feedstock 9, a quantity of an alkali metal 5 is added to the chamber 3. (The alkali metal is abbreviated as “AM.”) In some embodiments, the alkali metal may be sodium, lithium or alloys of sodium and lithium. The chamber 3 may be kept at a temperature that is above the melting point of the alkali metal 5 such that the liquid alkali metal 5 may easily be added to the liquid oil feedstock. In some embodiments, the reaction occurs at a temperature that is above the melting point of the alkali metal (or above a temperature of about 100° C.). In other embodiments, the temperature of the reaction is less than about 450° C.
When added to the chamber 3, the alkali metal 5 may react with the oil feedstock 9. More specifically, the alkali metal 5 reacts with the quantity of the naphthenic acids 8 to form a de-acidified feedstock 12. As inorganic acid products 13 may also be formed from this reaction, a product separator 10 may be used to separate the de-acidified oil feedstock 12 from the inorganic acid products. Those skilled in the art will appreciate how this separation may occur. Moreover, those skilled in the art will appreciate the structures (such as a settling chamber, etc.) that may be used as the product separator 10. The product separator 10 may be integral with the chamber 3 or may be a separate structure, as shown in
As explained herein, the reaction between the alkali metal 5 and the naphthenic acids 8 operates to eliminate the naphthenic acids 8 from the oil feedstock 9. Thus, the TAN value of the de-acidified oil feedstock 12 will be lower than the TAN value of the original (unreacted) first oil feedstock 9. For example, in some embodiments, the TAN value of the original (unreacted) oil feedstock 9 may be greater than or equal to 1 (such as, for example, 3, 4, 5, etc.) whereas the TAN value of the de-acidified oil feedstock 12 is a lower value, such as less than or equal to 1. As noted above, other acids in the oil feedstock 9 may contribute to the TAN value of the feedstock 9. These acids may also react with the alkali metal in a similar manner, further reducing the TAN value.
This reduction in TAN value may provide a significant financial benefit to the owner of the oil feedstock. As noted above, prices per barrel of oil products that are considered to be high TAN (e.g., with a TAN value greater than 1) are often discounted significantly with respect to barrels of oil products that are low TAN. Thus, by reducing the TAN value in the oil feedstock, the value of the oil feedstock may be significantly increased.
Referring now to
As described above, heavy metals 14 (such as nickel, vanadium, iron, arsenic, etc.) are often found in samples of oil feedstock materials 9. In some embodiments, it may be desirable to remove these heavy metals 14, as such metals can poison catalysts that are typically utilized in hydrocarbon processing. However, as shown in
As shown in
In addition to removing heavy metals, the alkali metal 5 may also react with one or more heteroatoms 11 (such as N, S) that are present in the oil feedstock 9. These N, S atoms may be bonded to the carbon/hydrogen atoms in the organic oil feedstock 9. However, as noted herein, the alkali metal 5 may react with these one or more heteroatoms 11 to form inorganic sulfur/nitrogen products 17. For example, if the alkali metal 5 is sodium, then the reaction with the heteroatoms 11 forms inorganic sulfur/nitrogen products 17 such as Na2S, Na3N and/or other inorganic products. (Again, a product separator 10 may be used to separate out the inorganic sulfur/nitrogen products 17 from the oil feedstock). Once the inorganic sulfur/nitrogen products 17 have been removed, the heteroatom to carbon ratio of the resulting oil feedstock is less than the heteroatom to carbon ratio of the original (unreacted) oil feedstock 9.
It should be noted that after the oil feedstock 9 has been de-acidified, demetalized, de-sulfurized and/or de-nitrogenized, then this oil feedstock is referred to as an “upgraded” oil feedstock 12a in that this material is better suited for further refining, commercialization, etc.
It should be noted that in the embodiment shown in
Likewise, it should be noted that in the embodiment of
In the embodiments shown in
Referring now to
The feedstock chamber 20 may be separated from the alkali metal source chamber 30 by an alkali metal ion conductive separator 25. The ion separator 25 may be comprised of ceramic materials generally known as Nasicon, sodium beta alumina, sodium beta prime alumina or sodium ion conductive glass if the alkali metal is sodium; or Lisicon, lithium beta alumina, lithium beta prime alumina or lithium ion conductive glass if the alkali metal is lithium. The materials used to construct the ion separator 25 are commercially available from Ceramatec, Inc., of Salt Lake City, Utah.
A cathode 26 which is negatively charged and connected to a power source 40 (via wires 42) may be, at least partially, housed within the feedstock chamber 20. Preferably the cathode 26 is located in close proximity to the ion separator 25 to minimize ionic resistance. The cathode 26 may be contacting the ion separator 25 (as shown in
The alkali metal source chamber 30 has an outer wall 31 and may have an inlet 32 and outlet 33. An anode 36 (which is positively charged) and connected to the power source 40 (via wires 42) may be, at least partially, housed within the source chamber 30. Suitable materials for the cathode 26 include materials comprising, carbon, graphite, nickel, iron which are electronically conductive. Suitable materials for the anode 36 include materials comprising titanium, platinized titanium, carbon, graphite. In the embodiment shown in
A mode of operation for the device 100 will now be described. Specifically, a first oil feedstock 50 may enter the feedstock chamber 20 (such as, for example, by flowing through the inlet 22). Concurrently, a dissolved solution of alkali metals 51 will flow through the alkali metal source chamber 30. This solution of alkali metals may be, for example, a solution of sodium sulfide, lithium sulfide, sodium chloride, sodium hydroxide, etc. A voltage is then applied to the anode 36 and cathode 26 from the source 40. This voltage causes chemical reactions to occur. These reactions cause alkali metal ions 52 (abbreviated “AM ions” 52″) to pass through the ion separator 25. In other words, the alkali metal ions 52 flow from the alkali metal source chamber 30, through the ion separator 25, into the feedstock chamber 20.
Once the alkali metal ions 52 (such as, for example, sodium ions or lithium ions) pass through the ion separator 25, the ions 52 are reduced to the alkali metal state 55 (e.g., into sodium metal or lithium metal) at the cathode 26. Once formed, the alkali metal 55 intermixes with the feedstock 50 (as shown by arrow 58). As described herein, the reaction between the oil feedstock 50 and the alkali metal 55 may involve a reaction between the acids (such as naphthenic acid) in the oil feedstock 50. Thus, the reaction with the alkali metal 55, which was formed in situ within the chamber 20, operates to reduce the acid content in the oil feedstock 50, thereby reducing the TAN value of the oil feedstock 50.
Additionally and/or alternatively, the reaction between the oil feedstock 50 and the alkali metal 55 formed within the chamber 20 may cause a reaction with the sulfur or nitrogen moieties within the oil feedstock 50. This reaction may also reduce heavy metals, such as vanadium and nickel in the feedstock 50. Further, as explained in the '874 application, at an elevated temperature and elevated pressure, the reaction between alkali metals 55 and the heteroatoms (S, N) forces the sulfur and nitrogen heteroatoms to be reduced by the alkali metals into ionic salts (such as Na2S, Na3N, Li2S, etc.). These ionic salts may then be removed from the oil feedstock 50. As such, the content of sulfur and nitrogen within the oil feedstock 50 may be significantly reduced by the reaction of the alkali metal 55 formed within the chamber 20. In other words, the heteroatom-to-carbon ratio of the upgraded oil feedstock may be less than the heteroatom-to-carbon ratio of the original (unreacted) oil feedstock. Also, the amount of heavy metals in the feedstock may further be reduced. Thus, the ratio of carbon to heavy metals in the upgraded (reacted) feedstock is less than the ratio of carbon to heavy metals in the original (unreacted) feedstock.
Further, in addition to the oil feedstock 50, the chamber 20 may also include a quantity of an upgradant hydrocarbon 60 that reacts with the oil feedstock 50 (as shown by arrow 74). Specifically, as taught by the '874 application, when the sulfur/nitrogen moieties of the oil feedstock 50 react with the alkali metals 55, radical species are formed that may react with the upgradant hydrocarbon 60. In some embodiments, the upgradant hydrocarbon 60 may be hydrogen gas, including the hydrogen gas formed by the reaction with naphthenic acid. (It should be noted that if hydrogen is used as the hydrocarbon 60, the amount of hydrogen needed is less than the amount of hydrogen that would be required if a typical hydrotreatment process were utilized). In other embodiments, the upgradant hydrocarbon 60 comprises natural gas, shale gas and/or mixtures thereof, methane, ethane, propane, butane, pentane, their isomers, ethene, propene, butene, pentene, dienes, and/or mixtures thereof. As explained in the '874 application, this reaction with the upgradant hydrocarbon 60 may operate to produce an upgraded hydrocarbon that has a greater hydrogen-to-carbon ratio than the original oil feedstock 60. The upgraded oil feedstock produced in the reaction may also have a greater energy value than the original oil feedstock 60. Typically the presence of upgradant hydrocarbon 60 may result in a reduction of formation of insoluble solids during the reaction. It is believed that these solids are large organic polymers that are formed as part of the radical reactions. However, by using the upgradant hydrocarbon 60, this hydrocarbon 60 acts as a “capping” species that prevents the formation of these solid, organic polymers. Thus, by using the hydrocarbon 60, the subsequent yield of the liquid oil feedstock (e.g., the desired product) may be increased.
The reactions described in
In some embodiments, the oil feedstock 50 may be passed through the device 100 (as the solution of sodium sulfide also passed through). Once passed through the device 100, the oil feedstock may flow into another vessel operated at a different temperature and pressure (e.g., temperatures and pressures more conducive to the reactions desired and where the residence time of the feedstock in the second vessel size is matched to the reaction kinetics and flow rates).
As described herein, various solids, inorganic compounds, etc., may be formed when performing the reactions outlined herein. These inorganic products may comprise Na2S, NaN3, heavy metals and solid organic polymers that are formed by the radical reactions. In order to deal with these inorganic compounds, the process used in conjunction with the device of
The oil feedstock 50, alkali metal solution 51 and other components of the device 100 may be dissolved in a polar solvent such as Formamide, Methyl formamide, Dimethyl formamide, Acetamide, Methyl acetamide, Dimethyl acetamide, Triethylamine, Diethyl acetamide, Ethylene glycol, Diethylene glycol, Triethylene glycol, Tetraethylene glycol, Ethylene Carbonate, Propylene Carbonate, Dimethylpropyleneurea, Butylene Carbonate, Cyclohexanol, 1,3-Cyclohexanediol, 1,2 Ethanediol, 1,2-Propanediol, Ethanolamine, Methyl sulfoxide, Dimethyl sulfoxide, Tetramethylene sulfoxide, Sulfolane, Gamma-butyrolactone, Nitrobenzene, Acetonitrile, Pyridine, quinoline, ammonia, ionic liquids or molten fused salts. For example, the alkali metal solution 51 may be dissolved in one or more of these solvents and then be allowed to flow into the alkali metal source chamber 30. (The salts that are used for the alkali metal solution 51 may be alkali metal chlorides, hydroxides, phosphates, carbonates, sulfides and the like.) Similarly, such solvents may be used with the oil feedstock 50 and/or the hydrocarbon 60 and then the mixture may be allowed to flow into the chamber 20.
Depending on the alkali metal source (e.g., the alkali metal solution 51), the anode reaction in the alkali metal source chamber 30 may vary. For example sulfides may form polysulfides and or elemental sulfur, chlorides may form chlorine gas, hydroxides may form oxygen gas, carbonates may form oxygen gas and evolve carbon dioxide and the like. If the alkali metal source is an alkali metal, metal ions will simply form. These variations constitute different embodiments. Gas handling and recovery may be a part of the overall process.
As shown in
Thus, as indicated herein, there are at least three different processes as part of this invention for de-acidifying these streams:
In the case of acid removal, there may not be any reason to add an upgradant hydrocarbon (gas) 60 to the feedstock chamber with the cathode since hydrogen gas may be a byproduct. As such, this formed hydrogen may act as the upgradant hydrocarbon 60. If heteroatoms such as sulfur, or nitrogen are present, an upgradent gas 60 such as hydrogen, natural gas, shale gas and/or mixtures thereof, may be needed.
It should also be noted that the addition of the alkali metal 102 may not simply neutralize the acidic hydrogen in the naphthenic acid. Specifically, naphthenic acid has the structure: R—COOH. In some embodiments, the alkali metal 102 may react with the oxygen atoms (in addition to the hydrogen atoms) such that the remaining hydrocarbon after the alkali metal addition has the structure R—CH3, R—H, etc. (The reason for this is that the alkali metal 102 may also reduce the oxygen moiety as well as the hydrogen moiety.) The formed inorganic products may thus include NaOH, Na2O, etc. As noted above, after reaction with the alkali metal 103, the TAN value of the feedstock 50 is reduced. However, given the above-recited reactions with the oxygen moieties, the TAN value may not be increased (or returned to its original state) by simply reacting the de-acidified oil feedstock with base (such as NaOH). Rather, as described herein, the reduction of the TAN value may also operate to convert the naphthenic or other acid groups into pure hydrocarbon functional groups (such as is R—CH3, R—H, etc.).
Referring now to
The embodiment of the device 100 that is shown in
As described herein, the oil feedstock 50 shown in
As shown by
Once in the chamber 20, the oil feedstock 50 (which has had the heavy metals removed) may then be reacted with a second quantity of the alkali metal 55b. This time, the alkali metal 55b reacts with the naphthenic acid to form a de-acidified oil feedstock, wherein a TAN value of the unreacted oil feedstock is less than a TAN value of the de-acidified oil feedstock. Again, after the acids have been reacted, the reacted oil feedstock 50 may be sent to the product separator 80 which may operate to remove the inorganic materials that were formed during the reaction with the second quantity of alkali metals 55b. This separation of inorganic materials may occur within the same product separator 80 that was used to remove the heavy metals or may be conducted in a different separator product 80.
After passing through the product separator 80, the feedstock 50 (minus the heavy metals and the naphthenic acids which were previously removed) may be brought back into the chamber 20. This chamber 20 may be the same chamber that was previously used to remove the heavy metals/naphthenic acids, or it may be a chamber 20 of a different device 100 that is positioned downstream from the product separator 80. Once in the chamber 20, the oil feedstock 50 (which has had the heavy metals/naphthenic acids removed) may then be reacted with a third quantity of the alkali metal 55c. This reaction with the third quantity of the alkali metal 55c removes at least one heteroatom (e.g., N, S) from the feedstock 50 to form an upgraded oil feedstock. The heteroatom to carbon ratio of the upgraded oil feedstock is less than a heteroatom to carbon ratio of the oil feedstock. Once again, this product may then pass through a product separator 80 to remove the inorganic materials and/or N, S moieties from the oil feedstock, thereby resulting in an upgraded oil feedstock.
It should be noted that the alkali metal quantities 55a, 55b, 55c in
Referring now to
This oil feedstock 50b may then be added to a chamber 110b. The chamber 110b may be the same chamber as the chamber 110a (e.g., the oil feedstock material is re-inserted into the chamber 110a) or it may be a different vessel. The chamber 110b may be referred to as a “de-acidification” chamber in that the oil feedstock 50b may be de-acidified in this chamber 110b. In order to conduct this reaction, the oil feedstock 50b is reacted with a quantity of an alkali metal (such as second quantity of the alkali metal 55b shown in
Once the reaction has occurred, the products may be placed within a product separator 80b. Those skilled in the art will appreciate the types of devices (such as a settling chamber) that may be used as the product separator 80b. The product separator 80b may be the same structure as the product separator 80a or may be a different element. In this product separator 80b, inorganic acid products 127 are separated out, leaving only a quantity of “de-acidified” oil feedstock 50c.
This de-acidified oil feedstock 50c (which has also been de-metalized) may then be added to a chamber 110c. This chamber 110c may be the same as either or both of the chambers 110a, 110b, or in other embodiments, the chamber 110c may be a different chamber than the chambers 110a, 110b. This chamber 110c may be referred to as a “de-sulfurization” chamber in that sulfur moieties from the oil feedstock may be removed. More specifically, an alkali metal (such as a third quantity of the alkali metal 55c) may be added to react with the oil feedstock. More specifically, this reaction involves reacting the alkali metal with a heteroatom, such as sulfur. (This reaction is described above). Once reacted, the products may be added to a product separator 80c which operates to remove inorganic sulfur products 129 from the oil feedstock, thereby producing de-sulfurized feedstock 50d.
This feedstock 50d may further be added to a chamber 110d. This chamber 110d may be the same as or different than the chambers 110a, 110b, 110c. In this chamber, heteroatoms such as nitrogen are removed from the oil feedstock by reacting the feedstock with an alkali metal quantity (such as, for example, alkali metal 55c of
In the embodiment shown in
Referring now to
In the embodiment of
The de-acidified feedstock 150b may be added to a chamber 20 so that it may be exposed to alkali metal 155b, thereby eliminating the heteroatoms and/or the heavy metals in the feedstock 150b. Thus,
The embodiment shown in
Once the heteroatoms/heavy metals have been removed by the chamber 20, the oil feedstock 150c may flow out of the chamber 20. This oil feedstock will be referred to as “upgraded” oil feedstock 150c.
Further, those skilled in the art will appreciate that the amount of alkali metal that is needed to reduce the TAN value below 1, to remove the heteroatoms, to react with the heavy metals, etc., will depend upon the particular sample of oil feedstock/hydrocarbon material. Accordingly, by performing testing on the sample oil feedstock, a skilled artisan can determine how much alkali metal may be needed to upgrade the oil feedstock.
All the patent applications and patents listed herein are expressly incorporated herein by reference.
This invention was made with government support under Contract No. DE-FE0000408 awarded by the U.S. Department of Energy. The government has certain rights in the invention.
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