Patent Publication Number: US-7901566-B2

Title: Reforming sulfur-containing hydrocarbons using a sulfur resistant catalyst

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation-in-part of and claims the benefit of priority of co-pending application Ser. No. 11/456,718 filed on Jul. 11, 2006, which is incorporated herein by reference. 
    
    
     TECHNICAL FIELD 
     The subject invention generally relates to reforming sulfur containing hydrocarbons without the need for in-process sulfur removal such as catalytic hydrodesulfurization or sulfur adsorbents. 
     BACKGROUND 
     Natural gas (of which the primary component is CH 4 ) contains lesser amounts of higher hydrocarbons such as alkanes alkenes and aromatics (or the general class of C2-C6+ hydrocarbons) which are prone, during catalytic processing such as pre-reforming and reforming reactions, to form coke deposits and deactivate the catalyst. 
     Coke formation often accompanies high temperature conversion processes that utilize hydrocarbon feed streams, and is detrimental to the operational efficiency of hydrocarbon reforming equipment. For example, the available reactive surface area of the reforming catalysts can be decreased by the undesirable deposition of coke on the surface of the catalyst. The deposition of coke on process equipment can also lead to inefficiencies in heat transfer, as well as unwanted pressure drops. 
     Difficulties associated with coke formation are of particular concern in reformers used for providing hydrogen to fuel cells since applications such as fueling stations and residential applications often mandate smaller scale reformer designs and a minimization of maintenance requirements. As such, equipment and maintenance provisions for the removal of coke that are available in an industrial setting such as in an ammonia plant are effectively unavailable for many fuel cell reformer applications. 
     The reforming or pre-reforming of ethane, as a surrogate for higher hydrocarbons is shown in the equations below.
 
Reforming: C 2 H 6 +2H 2 O 5H 2 +2CO
 
Pre-Reforming: C 2 H 6 +2H 2 O 3H 2 +CO(CO 2 )+CH 4  
 
Reforming is practiced in chemical plants designed to maximize the production of H 2  and CO from all hydrocarbons present in the feed while pre-reforming is mainly practiced at lower temperatures than reforming primarily to remove higher hydrocarbon coke precursors forming CO, H 2 , and CH 4 . Both pre-reforming and reforming can be practiced at a variety of pressures. Reduced nickel catalysts (such as Ni/Al 2 O 3 ) are commonly used for reforming reactions. However, nickel catalysts are highly susceptible to deactivation by small amounts of sulfur present in the feed. Deactivation is caused by nickel sulfide (NiS) formation which poisons the active Ni metal sites over time. The active Ni metal sites cannot be conveniently regenerated, and thus the deactivation process is essentially irreversible. Consequently, it is common practice to desulfurize the hydrocarbon feed prior to reforming. The hydrocarbon feed is desulfurized by catalytic hydrodesulfurization using Co, Mo/Al 2 O 3  catalysts at temperatures in excess of 350° C. and pressures above 300 psig. One concern with such a catalytic hydrodesulfurization is the production hydrogen sulfide (H 2 S) which is then adsorbed on ZnO downstream in the following manner.
 
                         
The necessity for sulfur removal is a critical limitation with the reforming process to avoid poisoning of downstream catalysts and equipment and thus large volumes of ZnO or other suitable adsorbents must be present in the process stream upstream from the reformer. These adsorbents have limited capacities for adsorbing hydrogen sulfide, and thus the adsorbents must be replaced frequently. The capacity of an adsorbent for adsorbing hydrogen sulfide is decreased with H 2 O in the feed gas, as well as temperature. The presence of an adsorbent in the process stream adds significantly to the overall pressure drop and process complications. This process is quite complicated and requires costly regeneration or disposal of the catalyzed-reactive hydrodesulfurization bed and replacement of sulfur saturated ZnO.
 
     Furthermore, sulfur removal is an important aspect in petroleum refining processes such as catalytic reforming, which play an integral role in upgrading straight run or cracked naphtha feedstocks, as by increasing the octane number of the gasoline fraction contained in such feedstocks. To achieve maximum run lengths and increase process efficiency, it is generally recognized that the sulfur content of the feedstock must be minimized. Reforming catalysts, and particularly those comprising platinum, and most particularly comprising platinum and rhenium, deactivate rapidly in the presence of sulfur compounds, and as a result, it is necessary to reduce the sulfur content of reformer feedstocks as low as possible. 
     SUMMARY 
     The following presents a simplified summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not an extensive overview of the invention. It is intended to neither identify key or critical elements of the invention nor delineate the scope of the invention. Rather, the sole purpose of this summary is to present some concepts of the invention in a simplified form as a prelude to the more detailed description that is presented hereinafter. 
     The subject invention provides for efficient reforming of sulfur containing hydrocarbons without the need for in-process sulfur removal such as catalytic hydrodesulfurization or sulfur adsorbants. Intermittent or continuous reforming methods can be employed. 
     Aspects of the invention relate to systems and methods of reforming a sulfur containing hydrocarbon involving contacting the sulfur containing hydrocarbon with a non-sulfating carrier and a sulfur tolerant catalyst containing one or more of a sulfur tolerant precious metal, a non-precious metal, and a non-precious metal oxide, (or any metal or metal oxide that adsorbs sulfur compounds) so that the sulfur tolerant catalyst adsorbs at least a portion of sulfur comprised in the sulfur containing hydrocarbon and a low sulfur reformate is collected. Periodically, the sulfur tolerant catalyst is contacted with a gas containing oxygen to convert at least a portion of adsorbed sulfur to a sulfur oxide that is desorbed and removed from the sulfur tolerant catalyst and specifically the non-sulfating carrier. The resultant sulfur oxide can be discharged to the atmosphere or adsorbed in an alkaline media dependent on local emission regulations. It should be understood that the non-precious metal or non-precious metal oxide can have some reforming activity; however, their main function is to adsorb sulfur from the feed gas providing a reservoir for storing sulfur allowing the sulfur tolerant precious metal to continue to reform for extended periods of time before regeneration becomes necessary. 
     To the accomplishment of the foregoing and related ends, the invention comprises the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative aspects and implementations of the invention. These are indicative, however, of but a few of the various ways in which the principles of the invention can be employed. Other objects, advantages and novel features of the invention will become apparent from the following detailed description of the invention when considered in conjunction with the drawings. 
    
    
     
       BRIEF SUMMARY OF THE DRAWINGS 
         FIG. 1  illustrates a schematic diagram of a system of reforming a sulfur containing hydrocarbon feed and desulfurizing a sulfur tolerant catalyst in one aspect of the invention. 
         FIG. 2  illustrates a schematic diagram of a system of reforming a sulfur containing hydrocarbon feed and desulfurizing/regenerating a sulfur tolerant catalyst in another aspect of the invention. 
         FIG. 3  illustrates a graphical diagram of process acts for reforming a sulfur containing hydrocarbon feed and desulfurizing/regenerating a sulfur tolerant catalyst in one aspect of the invention. 
         FIG. 4  illustrates a graphical diagram of reformate compositions in methods in accordance with an aspect of the invention. 
         FIG. 5  illustrates a graphical diagram of reformate compositions in methods in accordance with an aspect of the invention. 
         FIG. 6  illustrates a graphical diagram of reformate compositions in methods outside the scope of the invention. Here Al 2 O 3 , a sulfating carrier is used and shows only short term stability. 
         FIG. 7  illustrates a graphical diagram of reformate compositions in methods outside the scope of the invention. 
         FIG. 8  illustrates a graphical diagram of reformate compositions in methods outside the scope of the invention. 
         FIG. 9  illustrates a graphical diagram of reformate compositions in methods in accordance with an aspect of the invention. 
         FIG. 10  illustrates a graphical diagram of reformate compositions in methods in accordance with an aspect of the invention. 
     
    
    
     DETAILED DESCRIPTION 
     Hydrocarbon steam reforming, performed with a new process and sulfur tolerant catalysts, simplifies the entire pre-reforming and/or reforming operation by eliminating the need for in-process sulfur removal such as catalytic hydrodesulfurization and/or adsorption of sulfur compounds by ZnO. One aspect of the invention is the use of a sulfur tolerant reforming catalyst which can adsorb sulfur compounds, while continuing to reform the hydrocarbons. The invention allows for periodic sulfur removal from the sulfur tolerant reforming catalyst without substantial loss in activity or selectivity. The invention can be carried out in a simple reactor or a commonly used swing reactor. A swing reactor involves one reactor reforming while a parallel reactor is off-stream and the adsorbed sulfur compounds on the sulfur tolerant catalyst are catalytically oxidized by a pulse of O 2  liberating sulfur oxide such as SO 2 /SO 3 . The sulfur oxide is either vented to the atmosphere or easily adsorbed in an alkaline scrubber but external to the reforming process stream. Thus sulfur removal has no direct impact on the process reformate stream. 
     Referring to  FIG. 1 , a high level schematic diagram of a system  100  of reforming a sulfur containing hydrocarbon feed and desulfurizing/regenerating a sulfur tolerant catalyst in one aspect of the invention is shown. The system  100  contains a sulfur tolerant catalyst in a reactor vessel  102 . The reactor vessel  102  can have one or more inlets, such as three inlets, inlet  104  for injecting a sulfur containing hydrocarbon, inlet  108  for injecting steam, and inlet  112  for injecting a gas containing oxygen. The reactor vessel  102  can have one or more outlets, such as three inlets, outlet  106  for collecting reformate, outlet  110  for collecting combustible species, and outlet  114  for collecting a sulfur oxide. 
     A sulfur containing hydrocarbon is injected through inlet  104 . If the sulfur containing hydrocarbon is not previously mixed with steam, then steam is also injected through inlet  108 . Suitable reforming conditions are established and maintained, and reformate is collected via outlet  106 . The sulfur tolerant reforming catalyst has the ability to adsorb sulfur compounds present in the sulfur containing hydrocarbon. After a given time, but before the sulfur tolerant catalyst becomes saturated with sulfur and begins losing too much activity it becomes desirable to regenerate the sulfur tolerant catalyst in the reactor vessel  102 . The flow of sulfur containing hydrocarbon through inlet  104  is terminated, and optionally steam is injected through inlet  108  to purge the reactor vessel  102  combustible species. If present, the combustible species can be collected at outlet  110 . A gas containing oxygen is then injected through inlet  112 . The gas containing oxygen catalytically oxidizes the adsorbed sulfur compounds associated with the sulfur tolerant catalyst and converts them to a sulfur oxide thereby releasing the adsorbed sulfur compounds from the sulfur tolerant reforming catalyst. The sulfur oxide can be collected via outlet  114 . In addition or alternatively, absorbed sulfur can be removed from the sulfur tolerant catalyst and the sulfur tolerant catalyst regenerated by contacting the sulfur tolerant catalyst with a mixture containing hydrocarbon, steam, and oxygen to catalytically oxidize the hydrocarbon to generate an exotherm of sufficient intensity to remove at least a portion of the adsorbed sulfur. 
     Hydrocarbon reforming involves converting hydrocarbons to at least one of and typically at least two of CH 4 , H 2 , CO 2 , and CO. Examples of hydrocarbons that can be reformed include natural gas, alkanes containing from about 1 to about 12 carbon atoms and especially alkanes containing from about 1 to about 4 carbon atoms, alkenes containing from about 1 to about 12 carbon atoms and especially alkenes containing from about 1 to about 4 carbon atoms, aromatics containing from about 6 to about 16 carbon atoms such as naphtha, LPGs such as HD-5 LPG containing propane and propylene, diesel, gasoline, fossil fuels, jet fuel, and logistical fuels. 
     The hydrocarbons processed in accordance with the invention contain some sulfur, typically via a sulfur compound. Accordingly, the hydrocarbons processed in accordance with the invention are sulfur containing hydrocarbons. Examples of sulfur compounds include sulfur, hydrogen sulfide, carbonyl sulfide, carbon disulfide, thiophenes, mercaptans, sulfur oxides, sulfates, and sulfides. Sulfides include organic di-sulfides or inorganic compounds such as carbon monosulfides. The sulfur containing hydrocarbon feed may or may not contain water. 
     The sulfur containing hydrocarbon feed contains steam in addition to the sulfur containing hydrocarbon to facilitate reforming. In one embodiment, the sulfur containing hydrocarbon feed contains about 1% or more and about 99% or less of steam and about 1% or more and about 99% or less of the sulfur containing hydrocarbon. In another embodiment, the sulfur containing hydrocarbon feed contains about 10% or more and about 90% or less of steam and about 10% or more and about 90% or less of the sulfur containing hydrocarbon. In yet another embodiment, the sulfur containing hydrocarbon feed contains about 30% or more and about 80% or less of steam and about 20% or more and about 70% or less of the sulfur containing hydrocarbon. In this paragraph, % refers to % by volume. 
     The sulfur containing hydrocarbon feed alternatively contains steam and sulfur containing hydrocarbon in a steam to carbon ratio to facilitate reforming. In one embodiment, the sulfur containing hydrocarbon feed contains a steam to carbon ratio about 0.1 to about 10. In another embodiment, the sulfur containing hydrocarbon feed contains a steam to carbon ratio about 0.5 to about 5. 
     The terms reforming or steam reforming as used herein are intended to include all types of reforming reactions. Generally speaking, two commonly used reforming operations are high-temperature steam-reforming and moderate temperature pre-reforming. High-temperature steam-reforming tends to produce at least one of and typically at least two of H 2 , CO 2 , and CO while moderate temperature pre-reforming tends to produce at least one of and typically at least two of CH 4 , H 2 , CO 2 , and CO. High-temperature steam-reforming involves contacting a sulfur containing hydrocarbon feed with a reforming catalyst at temperatures of about 550° C. or more and about 900° C. or less and a pressure of about 1 atmosphere or more consistent with thermodynamics. In another embodiment, high-temperature steam-reforming involves contacting a sulfur containing hydrocarbon feed with a reforming catalyst at temperatures of about 600° C. or more and about 800° C. or less and a pressure of about 1 atmosphere or more or of about 1.1 atmosphere or more consistent with thermodynamics. 
     Moderate temperature pre-reforming involves contacting a sulfur containing hydrocarbon feed with a pre-reforming catalyst at temperatures of about 300° C. or more and about 550° C. or less and a pressure of about 1 atmosphere or more consistent with thermodynamics. In another embodiment, moderate temperature pre-reforming involves contacting a sulfur containing hydrocarbon feed with a pre-reforming catalyst at temperatures of about 400° C. or more and about 500° C. or less and a pressure of about 1 atmospheres or more or of about 1.1 atmospheres or more consistent with thermodynamics. The sulfur containing hydrocarbon feed in pre-reforming contains a fraction of the hydrocarbon with at least two carbon atoms. 
     The sulfur containing hydrocarbon feed gas is reformed over a sulfur tolerant precious metal catalyst which adsorbs the sulfur compounds while retaining its activity. Periodically the adsorbed sulfur is removed using a short air purge that catalytically converts the adsorbed sulfides to sulfur oxide which is easily scrubbed external to the process stream. 
                         
Regeneration with PM Catalyst
 
     In the above reactions, SC is a sulfur compound, m and n are individually integers from about 1 to about 25. 
     Examples of a sulfur tolerant catalyst include a non-sulfating carrier with one or more of a sulfur tolerant precious metal, a non-precious metal, and a non-precious metal oxide, where any non-precious metal and non-precious metal oxide present adsorbs sulfur deposited on such non-sulfating carrier. A sulfur tolerant catalyst has a catalytic activity that is hindered reversibly as a result of contact with sulfur compounds in the sulfur containing hydrocarbon feed gas. Insubstantial levels of catalytic activity degradation are acceptable. Thus, as used herein the definition of a sulfur tolerant catalyst is one whose activity is hindered but not permanently lost by the adsorption of sulfur compounds, as the sulfur tolerant catalyst can be regenerated. Also as used herein the definition of a non-sulfating carrier or support is a carrier that does not react to form sulfates. 
     The sulfur tolerant precious metal includes at least one of Pt, Pd, Rh, and Ir, and the like. In another embodiment, the sulfur tolerant precious metal includes at least two of Pt, Pd, Rh, and Ir. Other non-precious catalytic metals or promoters can additionally be included. Non-sulfating carriers contain at least one of silica, zirconia, and titania. Examples of non-sulfating carriers include or contain SiO 2 , ZrO 2 , SiO 2 —ZrO 2 , TiO 2 , SiO 2 —TiO 2 , ZrO 2 —TiO 2 , CeO—ZrO 2 , LaO—ZrO 2 , Y—ZrO 2 , zeolite materials (alumino-silicates), combinations thereof, and the like. An example of sulfating carrier is alumina which forms Al 2 (SO 4 ) 3 , and thus in one embodiment, the non-sulfating carriers do not contain unreacted or free alumina. 
     Non-precious metals and/or non-precious metal oxides that adsorb sulfur can be added to the sulfur tolerant catalysts to enhance the capacity for adsorption and/or improve other characteristics, so long as the ability to adsorb/desorb sulfur is not compromised. Useful non-precious metals and non-precious metal oxides include compounds or elements containing at least one atom from Periodic Groups VIIB, VIIB, VIIIB, IB, and IIB, as defined by the International Union of Pure and Applied Chemistry. Such non-precious metals and non-precious metal oxides are herein collectively referred to as non-precious metal compounds including non-precious metals in elemental form. General examples of non-precious metal compounds include Group VIB metals, Group VIB metal oxides, Group VIIB metals, Group VIIB metal oxides, Group VIII metals, Group VIII metal oxides, Group IB metals, Group IB metal oxides, Group IIB metals, Group IIB metal oxides, and the like. 
     Specific examples of non-precious metal compounds include Ni, NiO, Cu, CuO, Zn, ZnO, Cr, Cr 2 O 3 , Mn, MnO, Co, CoO, Fe, FeO, and Fe 2 O 3 . 
     Non-precious metal compounds can promote the formation of chemisorbed surface sulfides during reforming, which have the ability to decompose to SO 2 /SO 3  during the O 2  pulse, and decrease the rate of activity loss of any sulfur tolerant catalyst present due to sulfur surface absorption and/or sulfide formation on the sulfur tolerant precious metal. Non-precious metal compounds can also have intrinsic catalytic activity to catalyze reforming and pre-reforming reactions, especially with hydrocarbons heavier than methane. The major function of non-precious metal compounds, however, is to act as a reservoir for adsorbing sulfur compounds extending the time between regeneration acts. An embodiment of the sulfur tolerant catalyst includes both a sulfur tolerant precious metal and a non-precious metal compound; however, a functional embodiment of the sulfur tolerant catalyst can be formed from non-precious metal compounds, such as Ni, on a non-sulfating carrier or support without the inclusion of a sulfur tolerant precious metal. Likewise, a functional embodiment of the sulfur tolerant catalyst can be formed from the sulfur tolerant precious metal on a non-sulfating carrier or support without the inclusion of the non-precious metal compound. 
     The sulfur tolerant catalyst contains a sufficient amount of sulfur tolerant precious metal and/or transition metal compound to effect a reforming reaction. In one embodiment, the sulfur tolerant catalyst contains about 0.1% by weight or more and about 20% by weight or less of sulfur tolerant precious metal and about 80% by weight or more and about 99.9% by weight or less of a non-sulfating carrier. In another embodiment, the sulfur tolerant catalyst contains about 0.5% by weight or more and about 10% by weight or less of sulfur tolerant precious metal and about 90% by weight or more and about 99.5% by weight or less of a non-sulfating carrier. In yet another embodiment, the sulfur tolerant catalyst contains about 0.1% by weight or more and about 20% by weight or less of the sulfur tolerant precious metal, about 0.1% by weight or more and about 20% by weight or less of the transition metal compound, and about 60% by weight or more and about 99.8% by weight or less of a non-sulfating carrier. In still yet another embodiment, the sulfur tolerant catalyst contains about 0.5% by weight or more and about 10% by weight or less of the sulfur tolerant precious metal, about 0.5% by weight or more and about 10% by weight or less of the transition metal compound, and about 80% by weight or more and about 99% by weight or less of a non-sulfating carrier. 
     The non-sulfating carriers have a relatively high surface area to both disperse the precious metal and/or transition metal compound and adsorb sulfur compounds. In one embodiment, the surface area of the non-sulfating carriers is about 25 m 2 /g or more and about 300 m 2 /g or less. In another embodiment, the surface area of the non-sulfating carriers is about 50 m 2 /g or more and about 250 m 2 /g or less. In yet another embodiment, the surface area of the non-sulfating carriers is about 75 m 2 /g or more and about 200 m 2 /g or less. 
     The sulfur tolerant catalyst can be made by contacting and/or mixing the sulfur tolerant precious metal with the non-sulfating carrier and/or transition metal compound. For example, the sulfur tolerant catalyst can be made by contacting a non-sulfating carrier with a solution containing platinum and rhodium. Alternatively, the sulfur tolerant catalyst can be made by contacting a non-sulfating carrier with a first solution of a first sulfur tolerant precious metal such as platinum, followed by or simultaneously contacting the non-sulfating carrier with a second solution of a second sulfur tolerant precious metal such as rhodium (and/or a third solution with a third sulfur tolerant precious metal). The solution of sulfur tolerant precious metal can contain one or more sulfur tolerant precious metals, or two or more sulfur tolerant precious metals. 
     Likewise, the sulfur tolerant catalyst can be made by contacting and/or mixing the transition metal compound with the non-sulfating carrier. For example, the sulfur tolerant catalyst can be made by contacting and/or mixing a non-sulfating carrier with a solution containing nickel. To create a sulfur tolerant catalyst containing both the sulfur tolerant precious metal and the transition metal compound, the sulfur tolerant catalyst can be made by contacting and/or mixing the non-sulfating carrier with a solution containing a sulfur tolerant precious metal or metals, such as platinum and/or rhodium, and a transition metal compound, such as nickel. Alternatively, the sulfur tolerant catalyst can be made by contacting a non-sulfating carrier with a first solution of sulfur tolerant precious metals such as platinum and/or rhodium, followed by or simultaneously contacting the non-sulfating carrier with a second solution of a first transition metal compound, such as nickel (and/or a third solution of a second transition metal compound, etc.). 
     When the non-sulfating carrier is contacted with the sulfur tolerant precious metal and/or transition metal compound in solution, depending upon the amount of solution used and the wettability of the non-sulfating carrier, either a wet powder or a slurry is formed. A slurry can be optionally ball milled, then dried at a suitable temperature for a suitable period of time to yield a sulfur tolerant catalyst in powder form. In one embodiment, drying involves exposing the slurry in a chamber such as an oven to a temperature of about 30° C. or more and about 125° C. or less for a time from about 10 minutes to about 30 hours. In another embodiment, drying involves exposing the slurry in a chamber such as an oven to a temperature of about 40° C. or more and about 100° C. or less for a time from about 30 minutes to about 20 hours. 
     Various additives can be charged into the slurry or wet powder to facilitate formation of the sulfur tolerant catalyst in desired form (such as a formed shape or coating on a monolith substrate). Examples of such additives include binders, pH adjusters, drying agents, and the like. 
     The slurry contains a suitable amount of solids to form the sulfur tolerant catalyst in desired form, such as either a formed shape or a coating on a monolith substrate. In one embodiment, the slurry contains about 5% or more and about 95% or less of solids. In another embodiment, the slurry contains about 10% or more and about 90% or less of solids. 
     The sulfur tolerant catalyst can be heated at elevated temperatures for a suitable period of time before or after it is formed into any desired shape or before or after it is coated onto a substrate. In one embodiment, the sulfur tolerant catalyst is heated at a temperature of about 100° C. or more and about 850° C. or less for a time from about 10 minutes to about 50 hours. In another embodiment, the sulfur tolerant catalyst is heated at a temperature of about 200° C. or more and about 700° C. or less for a time from about 30 minutes to about 10 hours. In one embodiment, the optional heating can involve calcining the sulfur tolerant catalyst. 
     The sulfur tolerant catalyst can be in any form such as in particulate form, such as beads, pellets, powders, rods, quadralobes, and the like, and/or in layered washcoat compositions deposited on monolith substrates such as honeycomb monolith substrates or on metallic heat exchangers. 
     The sulfur tolerant catalyst can be formed from one or more catalyst layers on a monolith substrate or heat exchanger using a single catalyst layer, a double catalyst layer, or a triple catalyst layer. The individual catalyst layers can independently be formed from the sulfur tolerant precious metal, the non-precious metal compound, and a combination of the sulfur tolerant precious metal and the non-precious metal compound. Other layered configurations, such as zoned or graded configurations will be readily apparent to those of skill in the art, and include those disclosed U.S. Pat. No. 6,436,363, which is hereby incorporated by reference. The washcoat compositions used to form the layers of the sulfur tolerant catalyst typically contain a non-sulfating carrier impregnated with a sulfur tolerant precious metal and/or a non-precious metal compound. 
     In one embodiment, the monolith substrate is of the type comprising one or more monolithic bodies having a plurality of finely divided gas flow passages extending there through. Such monolith substrates are often referred to as “honeycomb” type substrates and are well known. The monolith substrate can be made of a refractory, substantially inert, rigid material which is capable of maintaining its shape and a sufficient degree of mechanical conditions at high temperatures, such as about 1400° C. Typically, a material is selected for use as the monolith substrate which exhibits a low thermal coefficient of expansion, good thermal shock resistance and low thermal conductivity. 
     Two general types of materials of construction for monolith substrates are readily available. One general type is a ceramic-like porous material composed of one or more metal oxides, e.g., alumina, alumina-silica, alumina-silica-titania, mullite, cordierite, zirconia, zirconia-cena, zirconia-spinel, zirconia-mullite, siliconcarbide, etc. Monolith substrates are commercially available in various sizes and configurations. The monolithic substrate can contain, for example, a cordierite member of generally cylindrical configuration (either round or oval in cross section) and having a plurality of parallel gas flow passages of regular polygonal cross sectional extending therethrough. The gas flow passages are typically sized to provide from about 50 to about 1,200 gas flow channels per square inch of face area. In another embodiment, the gas flow passages are typically sized to provide from about 200 to about 600 gas flow channels per square inch of face area. 
     The second general type of material of construction for the monolith substrate is a heat- and oxidation-resistant metal, such as stainless steel or an iron-chromium alloy. Monolith substrates are typically fabricated from such materials by placing a flat and a corrugated metal sheet one over the other and rolling the stacked sheets into a tubular configuration about an axis parallel to the configurations, to provide a cylindrical-shaped body having a plurality of fine, parallel gas flow passages, such as from about 200 to about 600 gas flow channels per square inch of face area. In another embodiment, the gas flow passages are typically sized to provide from about 200 to about 600 gas flow channels per square inch of face area. 
     In another embodiment, the monolith substrate is present in the form of a ceramic foam or metal foam. Monolith substrates in the form of foams are well known, e.g., see U.S. Pat. No. 3,111,396 and SAE Technical Paper 971032, entitled “A New Catalyst Support Structure For Automotive Catalytic Converters” (February 1997), both of which are hereby incorporated by reference. 
     In yet another embodiment, the sulfur-tolerant catalyst is coated as a washcoat composition on a monolith substrate which is in the form of a heat exchanger. A heat exchanger substrate can be a shell-and-tube exchanger, a crossflow monolith or a fin-type exchanger of the type commonly employed in automobile radiators. 
     The sulfur tolerant catalyst layer can be deposited directly on the surface of the monolith substrate. In the case of metallic honeycombs or heat exchangers, however, a binder coating can be deposited on the surface of a metallic substrate interposed between the surface of the monolithic substrate and the sulfur tolerant catalyst layer. Such binder coating is typically present in an amount of up to about 1 g/in 3  of the monolith substrate and can contain a high surface area material such as silica. 
     After a predetermined amount of time of reforming, the sulfur tolerant catalyst in the reaction chamber or vessel adsorbs a maximum amount of sulfur. At this time or before, the adsorbed sulfur is removed from the sulfur tolerant catalyst in a separate process act by contacting the sulfided sulfur tolerant catalyst with a gas containing oxygen to convert at least a portion of adsorbed sulfur to a sulfur oxide that is desorbed from the sulfur tolerant catalyst external to the reforming process act. 
     Optionally after contacting the sulfur tolerant catalyst with the sulfur containing hydrocarbon and before contacting the sulfided sulfur tolerant catalyst with a gas containing oxygen, the sulfided sulfur tolerant catalyst is contacted with steam. That is, a steam purge can be injected into the reaction chamber or vessel to remove combustible gases to mitigate possible complications in regenerating the sulfur tolerant catalyst. 
     The steam purge is conducted at a temperature low enough to avoid substantial desorption of sulfur compounds. In one embodiment, the steam purge is conducted at about 600° C. or less. In another embodiment, the steam purge is conducted at about 500° C. or less. In yet another embodiment, the steam purge is conducted at about 400° C. or less. 
     The steam purge is conducted for a sufficient time to remove combustible gases from the reaction chamber or vessel. In one embodiment, the steam purge is conducted for a time of about 0.1 second or more and about 20 minutes or less. In another embodiment, the steam purge is conducted for a time of about 1 second or more and about 10 minutes or less. In yet another embodiment, the steam purge is conducted for a time of about 10 seconds or more and about 5 minutes or less. 
     The gas containing oxygen contains at least oxygen, and can contain other components such inert gases, steam, ozone, carbon dioxide, and the like. Inert gases include nitrogen, helium, neon, argon, krypton, and xenon. An example of an inexpensive oxygen containing gas is air. In one embodiment, the gas contains at least about 5% by volume oxygen. In another embodiment, the gas contains at least about 10% by volume oxygen. In yet another embodiment, the gas contains at least about 20% by volume oxygen. 
     In a regenerating act, the adsorbed sulfur is catalytically converted by the precious metal sulfur tolerant catalyst and/or by the transition metal compound by the addition of O 2  to a sulfur oxide, such as SO 2  and/or SO 3 . The sulfur oxide(s) can be emitted to the atmosphere or treated, for example, scrubbed in an alkaline solution, and then emitted. To regenerate the sulfided catalyst, a relatively short pulse of an oxygen containing gas is contacted with the sulfur tolerant catalyst containing the adsorbed sulfur. In one embodiment, air is injected into the reaction chamber to produce easily scrubbed sulfur oxide external to the process stream. It should be noted that steam alone is not sufficient to remove adsorbed sulfur from the sulfided sulfur tolerant catalyst at about 500° C. In another embodiment, a regenerating act includes catalytically oxidizing a hydrocarbon to generate an exotherm of sufficient intensity to remove at least a portion of the adsorbed sulfur by contacting the sulfided sulfur tolerant catalyst with a mixture containing hydrocarbon, steam, and oxygen. The sulfur compounds removed and the products of the oxidation can be emitted to the atmosphere or treated, for example, scrubbed in an alkaline solution, and then emitted. 
     When the regeneration act employing a gas containing oxygen is performed, the gas containing oxygen is contacted with the sulfided sulfur tolerant catalyst at a temperature to promote catalytic conversion of a majority of the adsorbed sulfur compounds to a sulfur oxide. In one embodiment, the oxygen containing gas is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 200° C. or more and 800° C. or less. In another embodiment, the oxygen containing gas is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 300° C. or more and 700° C. or less. In yet another embodiment, the oxygen containing gas is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 400° C. or more and 600° C. or less. Majority means at least 50% by weight. 
     The gas containing oxygen is contacted with the sulfided sulfur tolerant catalyst for a sufficient time to promote conversion of a majority of the adsorbed sulfur compounds to a sulfur oxide. The time can vary greatly in different embodiments and depends upon a number of factors including the amount of oxygen in the oxygen containing gas, the level of regeneration desired, and the like. In one embodiment, the oxygen containing gas is contacted with the sulfided sulfur tolerant catalyst for a time of about 1 second or more and about 30 minutes or less. In another embodiment, the steam purge is conducted for a time of about 10 seconds or more and about 10 minutes or less. In yet another embodiment, the steam purge is conducted for a time of about 20 seconds or more and about 5 minutes or less. 
     The sulfur oxide(s) released is disposed of in any suitable manner. For example, the sulfur oxide is can be vented to the atmosphere, collected and stored for a subsequent use, adsorbed in a scrubber, such as an alkaline scrubber. Generally speaking, disposal of the sulfur oxide is external to the reforming process. 
     When the regeneration act employing a gas containing hydrocarbon, steam, and oxygen is performed, the mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst at a temperature to promote catalytic conversion of the hydrocarbons to combustion products resulting in an exotherm of sufficient intensity of heat to remove at least a portion of the adsorbed sulfur. An exotherm of sufficient intensity to remove at least a portion of the adsorbed sulfur is generated by contacting the mixture containing hydrocarbon, steam, and oxygen with the sulfided sulfur tolerant catalyst at a temperature high enough to catalytically oxidize the hydrocarbon. In one embodiment, the mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 200° C. or more and 800° C. or less. In another embodiment, the mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 300° C. or more and 700° C. or less. In yet another embodiment, the mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst at a temperature of about 400° C. or more and 600° C. or less. In one embodiment, the majority of the adsorbed sulfur on the sulfided sulfur tolerant catalyst is removed. Majority means at least 50% by weight. 
     In one embodiment, the mixture containing hydrocarbon, steam, and oxygen contains about 10% or more and about 90% or less of steam, about 10% or more and about 90% or less of hydrocarbon, and at least about 5% or more of oxygen. In another embodiment, the mixture containing hydrocarbon, steam, and oxygen contains about 30% or more and about 80% or less of steam, about 20% or more and about 70% or less of hydrocarbon, and at least about 5% or more of oxygen. The oxygen in the mixture containing hydrocarbon, steam, and oxygen can be supplied by air. In this paragraph, % refers to % by volume. 
     The mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst for a sufficient time to allow the exotherm to remove a majority of the adsorbed sulfur compounds. The time can vary greatly in different embodiments and depends upon a number of factors including the amount of oxygen in the mixture containing hydrocarbon, steam, and oxygen, the level of regeneration desired, and the like. In one embodiment, the mixture containing hydrocarbon, steam, and oxygen is contacted with the sulfided sulfur tolerant catalyst for a time of about 1 second or more and about 30 minutes or less. In another embodiment, the mixture containing hydrocarbon, steam, and oxygen is conducted for a time of about 10 seconds or more and about 10 minutes or less. In yet another embodiment, the mixture containing hydrocarbon, steam, and oxygen is conducted for a time of about 20 seconds or more and about 5 minutes or less. 
     The sulfur compounds and oxidation products released as a result of the exotherm are disposed of in any suitable manner. For example, the sulfur compounds and oxidation products can be vented to the atmosphere, collected and stored for a subsequent use, and adsorbed in a scrubber, such as an alkaline scrubber. Generally speaking, disposal of the sulfur compounds and oxidation products is external to the reforming process. 
     As a result of the desulfurizing aspect of the invention, the reforming products produced are low sulfur reformates in that the reformate contains a markedly smaller amount of sulfur that the sulfur containing hydrocarbon feed. In one embodiment, the low sulfur reformate (at least one of and typically at least two of CH 4 , H 2 , CO 2 , and CO) contains about 20% or less of the amount of sulfur in the sulfur containing hydrocarbon feed. In another embodiment, the low sulfur reformate contains about 10% or less of the amount of sulfur in the sulfur containing hydrocarbon feed. In yet another embodiment, the low sulfur reformate contains about 5% or less of the amount of sulfur in the sulfur containing hydrocarbon feed. 
     In one embodiment, the low sulfur reformate (at least one of and typically at least two of CH 4 , H 2 , CO 2 , and CO) contains less than about 0.1 ppm of sulfur (or sulfur containing compounds). In another embodiment, the low sulfur reformate contains less than about 0.01 ppm of sulfur. In yet another embodiment, the low sulfur reformate contains less than about 0.001 ppm of sulfur. In still yet another embodiment, the low sulfur reforming products produced contain no detectable sulfur. 
     Referring to  FIG. 2 , a swing reactor system/operation  200  is shown demonstrating the efficient and simultaneous reforming of a sulfur containing hydrocarbon feed and desulfurizing/regenerating the sulfur tolerant catalyst. The swing reactor system/operation  200  has two vessels or reactors  202  and  204  that contain sulfur tolerant catalyst. The sulfur tolerant catalyst in vessels  202  and  204  can be the same or different. 
     The sulfur containing hydrocarbon feed gas enters through line  206  into vessel  202  and is reformed and the reformate is collected via line  212 . The sulfur compounds present in the sulfur containing hydrocarbon feed gas are adsorbed onto the sulfur tolerant catalyst without showing any evidence of catalyst deactivation. After a predetermined time on stream the sulfur containing hydrocarbon feed gas is diverted to parallel vessel  204  to continue the reforming process. An optional purge of steam is sent through line  208  through vessel  202  to remove combustible gases. A relatively short pulse of air is injected through line  210  into the steam flowing into vessel  202  after or with the steam flowing into vessel  202  and consequently the adsorbed sulfur compounds are catalytically converted to a mixture of SO 2 /SO 3  which desorbs from the sulfur tolerant catalyst. The sulfur oxide mixture is vented to the atmosphere through line  212 . 
     During the optional purge and air injection into vessel  202 , reforming and simultaneously desulfurization of the sulfur containing hydrocarbon feed gas is occurring in vessel  204 . The sulfur containing hydrocarbon feed gas is then redirected back into vessel  202  while sulfur removal and regeneration occurs in vessel  204  completing the total swing cycle. Thus, an intermittent process ( FIG. 1 ) or a continuous process ( FIG. 2 ) for reforming a sulfur containing hydrocarbon feed can be conducted. 
       FIG. 3  shows one embodiment of the sequence of process acts for reforming and regeneration. Steam can be continuously injected in to the reactor and contacted with the sulfur tolerant catalyst, while either a sulfur containing hydrocarbon feed, and gas containing oxygen, nothing, or an inert gas are additionally contacted with the sulfur tolerant catalyst. In this context, the optional steam purge is conducted by terminating injection of any other gas into the reactor, except for flow through the steam line. The process acts of  FIG. 3  are used to generate the data in  FIGS. 4-7 , as discussed below. 
     The following examples illustrate the subject invention. Unless otherwise indicated in the following examples and elsewhere in the specification and claims, all parts and percentages are by weight, all temperatures are in degrees Centigrade, and pressure is at or near atmospheric pressure. 
     Either a silica-zirconia carrier available from Magnesium Electron, Inc. of Flemington, N.J. or gamma alumina was mixed with nitrate salts of platinum and rhodium in an aqueous solution to impregnate the carrier with platinum and rhodium. The mixtures were dried at about 100° C. and subjected to calcination in air at about 500° C. 
       FIG. 4  demonstrates the reforming of sulfur-containing natural gas containing methane and higher hydrocarbons on Day 1. The y-axis represents the mole % of the reformate products. Compositions are dry gas.  FIG. 4  demonstrates the reforming of sulfur containing pipeline natural gas containing methane, ethane, and higher hydrocarbons at 500° C. utilizing the sulfur tolerant catalyst (Pt, Rh/SiO 2 /ZrO 2 ) catalyst and related methodology of the invention at atmospheric pressure. The process acts used to generate the data are shown in  FIG. 3 . 
       FIG. 5  demonstrates the reforming of sulfur-containing natural gas containing methane and higher hydrocarbons on Day 6 using the catalyst of Example 3. The y-axis represents the mole % of the reformate products. Compositions are dry gas. Pipeline natural gas containing greater than 90% methane, with the balance being higher hydrocarbons, especially ethane, with sulfur content varying from 0.5 to 2.5 ppm was mixed with steam (steam/carbon=1.4) at 500° C. inlet temperature and atmospheric pressure. Ethane conversion is shown as a surrogate for all higher hydrocarbons because it is the most difficult to steam reform excluding methane. Throughout the entire reforming process of  FIG. 4  the ethane is completely converted, the produced hydrogen is essentially constant and the methane shows a slight increase indicating a steady decrease in methane conversion likely due to the adsorption of sulfur and the possibility of some methanation. After the O 2  purge the activity as measured by the H 2  generated returns to its constant value showing reversibility. If the reforming process described in the invention is allowed to continue for 5 days ( FIG. 5 ) the H 2  generation remains high demonstrating the stability of the sulfur resistant catalyst and the effectiveness of the process. 
     These experiments are in contrast to the same precious metals but deposited on a sulfating support such as Al 2 O 3 . In  FIG. 6  reforming process acts of  FIG. 3  are applied to a Pt, Rh/Al 2 O 3  catalyst on Day 1. The y-axis represents the mole % of the reformate products. Compositions are dry gas.  FIG. 6  shows the same run conditions as  FIG. 4  but with a sulfating support. When using a sulfating support, the initial catalyst performance is good. However, after continuing to repeat the process described in  FIG. 3  for 5 days, as shown in  FIG. 7 , the H 2  concentration continues to decrease after each cycle while the increase in gas phase CH 4  is indicative of a loss of methane steam reforming activity. While not wishing to be bound by any theory, it is speculated that the O 2  purge causes formation of sulfur oxides which irreversibly reacts with the Al 2 O 3  leading to pore blockage and subsequent deactivation of the catalyst. 
     In  FIG. 7  reforming process acts of  FIG. 3  are applied to a Pt, Rh/Al 2 O 3  on Day 6. The y-axis represents the mole % of the reformate products. Compositions are dry gas.  FIG. 7  shows that when the catalyst prepared with a carrier susceptible to sulfating is operated continuously until complete loss of activity (H 2  yield) the O 2  pulse step is not completely effective in fully regenerating the catalyst since it does not remove all the sulfate Al 2 (SO 4 ) 3  formed. This is to be contrasted with the same precious metal components deposited on the non-sulfating carrier which can be completely regenerated as shown in  FIGS. 4 and 5 . 
       FIG. 8  demonstrates the effect of continuous exposure to a sulfur containing fuel on the steam reforming activity of a Pt, Rh on Al 2 O 3 .  FIG. 9  demonstrates the effect of continuous exposure to sulfur containing fuel on the steam reforming activity of a Pt, Rh on SiO 2 —ZrO 2 . 
     If the process of  FIG. 3  is not followed and if natural gas steam reforming in the presence of sulfur is performed under constant fuel/steam flow, the results show monotonically decreasing activity as demonstrated by increasing methane concentration, increasing ethane concentration, and decreasing hydrogen concentration. The data in  FIG. 8  are collected at SCR=1.6 with Pt, Rh on Al 2 O 3 , which is a substrate that can form stable sulfate species under these steam reforming conditions. A similar plot is obtained for the sulfur tolerant catalyst of the invention, such as Pt, Rh/SiO 2 /ZrO 2  ( FIG. 9 ) but the level of activity is retained considerably longer. The sulfur capacity of the catalyst can be estimated from the amount of sulfur adsorbed up to the time of extinction of activity. 
       FIG. 10  demonstrates the reforming of sulfur-containing natural gas containing methane and minor components of ethane, propane, and butane using a transition metal compound containing nickel as a catalyst on a non-sulfating support. A silica-zirconia carrier available from Magnesium Electron, Inc. of Flemington, N.J. was mixed with nickel nitrate in an aqueous solution to impregnate the carrier with nickel. The mixture were dried at about 10° C. and subjected to calcination in air at about 500° C.  FIG. 10  demonstrates the reforming of sulfur containing pipeline natural gas containing methane, ethane, butane, and other higher hydrocarbons at 500° C. utilizing the non-precious metal sulfur tolerant catalyst Ni/SiO 2 —ZrO 2  and related methodology disclosed herein at atmospheric pressure. The process acts used to generate the data presented in  FIG. 10  are shown in  FIG. 3 . In  FIG. 10 , the y-axis represents the mole % of the reformate products. In addition, the initial natural gas composition is indicated along the y-axis. The major natural gas component, methane, is not shown. Nickel has much less catalytic activity in comparison to Pt, Rh catalysts on silica-zirconia carrier disclosed herein. However, significant reformation of butane into hydrogen is observed. The butane reformation activity decreases over time likely due to the adsorption of sulfur. However, after the O 2  purge to regenerate the nickel catalyst, the butane reformation activity returns to the original level showing reversibility. It is feasible that non-precious metal compounds can be used as the sole catalyst. 
     In addition, non-precious metal compounds on a non-sulfating support can be used in combination with sulfur tolerant precious metal catalysts wherein the non-precious metal compounds provide a sink for sulfur allowing for an extension of time between regeneration acts. The fact that Ni can adsorb sulfur and can be regenerated demonstrates that it can act as both a reforming catalyst and an adsorbent of sulfur. 
     With respect to any figure or numerical range for a given characteristic, a figure or a parameter from one range may be combined with another figure or a parameter from a different range for the same characteristic to generate a numerical range. 
     While the invention has been explained in relation to certain embodiments, it is to be understood that various modifications thereof will become apparent to those skilled in the art upon reading the specification. Therefore, it is to be understood that the invention disclosed herein is intended to cover such modifications as fall within the scope of the appended claims.