Patent Publication Number: US-2022212949-A1

Title: Black powder catalyst for hydrogen production via dry reforming

Description:
TECHNICAL FIELD 
     This disclosure relates to hydrogen production via dry reforming of hydrocarbon. 
     BACKGROUND 
     Hydrogen is commercially produced, such as from fossil fuels. Hydrogen may be produced, for example, through reforming of hydrocarbons or electrolysis of water. Hydrogen is produced by coal gasification, biomass gasification, water electrolysis, or the reforming or partial oxidation of natural gas or other hydrocarbons. The produced hydrogen can be a feedstock to chemical processes, such as ammonia production, aromatization, hydrodesulfurization, and the hydrogenation or hydrocracking of hydrocarbons. The produced hydrogen can be a feedstock to electrochemical processes, such as fuel cells. 
     Carbon dioxide is the primary greenhouse gas emitted through human activities. Carbon dioxide (CO2) may be generated in various industrial and chemical plant facilities. At such facilities, the utilization of CO2 as a feedstock may reduce CO2 emissions at the facility and therefore decrease the CO2 footprint of the facility. The conversion of the greenhouse gas CO2 into value-added feedstocks or products may be beneficial. The reforming of hydrocarbon (e.g., methane) may utilize CO2. 
     The reforming of natural gas is the most prevalent source of hydrogen production. Bulk hydrogen is typically produced by the steam reforming of natural gas (methane). Steam reforming includes heating the natural gas (e.g., to between 500° C. to 1100° C.) in the presence of steam. Conventional catalyst employed includes, for example, nickel, nickel alloys, or magnesium oxide (MgO). This endothermic reaction generates CO and H2. 
     SUMMARY 
     An aspect relates to a method of dry reforming hydrocarbon, including reacting the hydrocarbon with carbon dioxide via reforming catalyst to generate synthesis gas including hydrogen and carbon monoxide, wherein the reforming catalyst includes treated black powder having hematite. 
     Another aspect relates to a method of dry reforming hydrocarbon, including providing hydrocarbon and carbon dioxide to a dry reformer vessel, wherein reforming catalyst including treated black powder is disposed in the dry reformer vessel. The method includes dry reforming the hydrocarbon in the dry reformer vessel via the reforming catalyst to generate hydrogen and carbon monoxide, and discharging the hydrogen and carbon monoxide from the dry reformer vessel. 
     Yet another aspect relates to a method of preparing a reforming catalyst for dry reforming methane, including receiving black powder and applying heat to the black powder to give heat-treated black powder. The method includes applying heat to the heat-treated black powder in presence of air to give a calcined black powder for dry reforming of methane, wherein a majority of the calcined black powder is hematite. 
     Yet another aspect relates to a reforming catalyst including calcined black powder for dry reforming methane with carbon dioxide, wherein the calcined black powder is black powder (from a natural gas pipeline) heat treated at a temperature of at least 500° C. for at least 3 hours and calcined at a temperature of at least 775° C. in presence of air for at least 4 hours. A majority of the calcined black powder is hematite. 
     Yet another aspect is a dry reformer including a dry reformer vessel having at least one inlet to receive methane and carbon dioxide. The dry reformer vessel has a reforming catalyst including calcined black powder to convert the methane and the carbon dioxide into syngas. The dry reformer vessel has an outlet to discharge the syngas, wherein the syngas includes hydrogen and carbon monoxide. 
     The details of one or more implementations are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  is a diagram of a pipe having black powder. 
         FIG. 2  is an x-ray diffraction (XRD) spectra of a sample of treated black powder. 
         FIG. 3  is a diagram of a dry reformer for dry reforming hydrocarbon. 
         FIG. 4  is a block flow diagram of a method of dry reforming hydrocarbon. 
         FIG. 5  is a block flow diagram of method of preparing a reforming catalyst for dry reforming hydrocarbon (e.g., CH4). 
         FIG. 6  is a plot of the percent of H2 in effluent over time for the Example. 
     
    
    
     DETAILED DESCRIPTION 
     Some aspects of the present disclosure are directed to collecting and processing black powder to give a catalyst (having hematite) that is utilized as reforming catalyst in dry reforming of methane. The catalyst is the processed black powder and thus may be labeled as a derivative of black powder. The processing of the black powder may include both heat treatment (e.g., at least 500° C.) and subsequent calcination (e.g., at least 775° C.). The treatment of the black powder gives the catalyst having Iron(III) oxide (Fe2O3) also known ferric oxide or hematite. This processing increases the amount of hematite (Fe2O3) in the black powder. Hematite (Fe2O3) is amphoteric and may be beneficial for catalysis in dry reforming of methane into syngas. Aspects of the present techniques relate to hydrogen production via dry reforming of hydrocarbon (e.g., methane) utilizing calcined black powder as the reforming catalyst. 
     Embodiments may heat treat and calcine black powder to give the treated black powder as having predominantly Fe2O3 (amphoteric). This treated (calcined) black powder may be employed as a dry reforming catalyst. The amphoteric (acidic basic) characteristic of the calcined black powder may provide basic sites for CO2 disassociation as well as acidic sites for methane cracking. This may help in diminishing the need for adding or impregnating metals (precious or non-precious) that might be utilized with dry reforming catalysts. In addition, black powder as a waste in the oil and gas industry is beneficially utilized. 
     In general, black powder is a solid contaminant often found in hydrocarbon gas pipelines. Black powder is debris in natural-gas pipelines formed by corrosion of the pipeline, such as on the inner surface of inside diameter of the pipe. The black powder may be formed by corrosion of the internal surface of the pipeline wall. The term “black powder” describes regenerative debris formed inside natural gas pipelines due to corrosion of the internal wall of the pipeline. Black powder is generally regarded as a chronic nuisance that may be removed from the pipeline system, for example, by the use of a separator or cyclone. Black powder is considered a continuing problem as unwanted material removed from valuable process streams via filter bags, separators, or cyclones, and so on. The material may be wet, for example, having a tar-like appearance. The black powder be a very fine, dry powder. Black powder is primarily composed of iron oxides, silica and other metal carbonates, hydroxides, and sulfide iron carbonates. Black powder can include mill-like scale, such as hematite (Fe2O3) and magnetite (Fe3O4). Black powder is a waste present in the natural gas industry in relatively large amounts. Limited efforts have been exerted to utilize black powder, despite its availability in large amounts at almost no cost. The black powder can be collected from the pipelines, such as by a separator or from filters employed in upstream portions of gas refineries. Gas refineries may include natural gas processing plants or similar processing sites or facilities. The upstream filters (e.g., coreless filters) may be located before the gas processing plant (refineries) along the pipeline from the wellhead of the gas well (or oil and gas well). Also, these filters may be located at the inlet of gas processing plant refineries. The black powder may be collected from the filter units as the filter units are opened and cleaned, or collected as dumped nearby the filtration. In present embodiments, the black powder as retrieved may be transported to the treatment. 
     Black powder is primarily found in gas pipelines between the wellhead and the natural gas processing plant. Black powder may be generally absent from gas pipelines downstream of the natural gas processing plant because acid gas (hydrogen sulfide and carbon dioxide), mercury, water, and gas condensate will have generally been removed from the natural gas. The removal of these contaminants reduces occurrence of black powder downstream of the natural gas processing plant. 
     Dry reforming may be beneficial for consuming the two greenhouse gases methane (CH4) and carbon dioxide (CO2). Dry reforming is a process that may react CH4 with CO2 to produce synthesis gas (syngas) with the aid of catalyst. The syngas may include hydrogen (H2) and carbon monoxide (CO). The dry reforming reaction may be characterized as CH4+CO2→2H2+2CO. Dry reforming can be processed on certain metal catalysts. Noble catalysts, such as ruthenium (Ru), rhodium (Rh), and platinum (Pt), in dry reforming have demonstrated applicable catalytic actively, selectivity, stability, and low coking. However, the high cost of these metals may restrict their commercial application. The transition metal nickel (Ni) has shown acceptable results in dry reforming but is susceptible to sintering and deactivation. In contrast, as indicated, present embodiments provide for treated black powder as an effective dry-reforming catalyst. 
     Black powder as heat treated and calcined may be employed as a catalyst for dry reforming process because the black powder catalyst may primarily be Fe2O3, The Fe2O3 being amphoteric may promote contemporaneous CH4 cracking, CO2 disassociation, and oxidation of carbon species on the catalyst surface without the need to add or impregnate precious or non-precious metals nor the prerequisite to have specific basic sites on the catalyst substrate (support). Thus, calcined black powder may be beneficial as a catalyst for dry reforming because black powder as calcined in an air environment mainly consists (greater than 50 weight percent) of Fe2O3 (amphoteric) that can allow the simultaneous occurrence of CH4 cracking and CO2 dissociation in the dry reformer reactor. The black powder catalyst having primarily amphoteric Fe2O3 may allow such simultaneous occurrence without the need to add or impregnate metals (precious or non-precious) nor the need to have specific basic sites (e.g., mainly for CO2 disassociation) on the substrate of the catalyst. The term “amphoteric” may generally refer to a compound, such as a metal oxide or hydroxide, able to react both as a base and as an acid. The implementation of black powder catalyst in dry reforming may facilitate use of greenhouse gases CH4 and CO2, as well as waste material (black powder), to produce the valuable commodity syngas (CO and H2). 
       FIG. 1  is a pipe  100  (conduit) that may be piping or pipeline in a hydrocarbon gas (natural gas) system. The pipe  100  has a pipe wall  102  having a wall thickness. Black powder  104  is collected along the inner surface  106  of the pipe  100 . The inner surface  106  is the internal surface of the inside diameter of the pipe  100 . As indicated, black powder is regenerative and formed inside natural gas pipelines because of corrosion of the inner surface  106 . Black powder forms through chemical reactions of iron (Fe) in ferrous pipeline steel with condensed water containing oxygen, CO2, and other gases. Black powder is mainly composed of iron hydroxides, iron oxides, and iron carbonates. The phrase “black powder” refers to the residue (material) that is formed along inner surface of pipelines as a natural waste product as a result of corrosion and includes metal oxide. Again, black powder can be collected from upstream filters employed in gas refineries. For many years, pipeline companies have observed the presence of black powder and its effects, but have viewed black powder generally only as an annoyance and therefore have done little to understand or use black powder. Instead, pipeline companies have primarily sought ways of removing the black powder from the pipelines. There are several approaches to remove the black powder, such as via separators and cyclones, where the black powder-laden gas passes through these devices and the black powder particles are physically knocked out of the gas stream. For instance, the black powder particles are removed from the gas stream and attach to the walls of the device (e.g., separator, cyclone) where they fall and are collected at the bottom in a collection media. Pipeline companies generally do not recognize a beneficial use for the black powder. Throughout the world, black powder from gas pipelines exists in large amounts, and is thus readily available at a very low cost due to its perceived lack of value. Black powder is typically discarded as waste. As mentioned, in many cases, black powder is regenerative debris that is formed inside natural gas pipelines as a result of corrosion of the internal walls of the pipeline. Black powder can also be collected from upstream filters or filter bags in gas refineries. 
     The typical major mineral composition of black powder without treatment is primarily iron oxide. The iron oxide includes magnetite (Fe3O4) and hematite (Fe2O3). The black powder also includes quartz (SiO2) and may include, metal carbonates, metal hydroxides, and sulfide iron carbonates. The Table below gives the elemental composition of a sample of example black powder “as is” (as collected) and also after the sample as “heat treated” (heat treatment at 500° C. for at least 3 hours). The heat treatment at 500° C. removes carbon associated with the metals, as indicated in the Table. The elements listed in the Table are carbon (C), oxygen (O), magnesium (Mg), silicon (Si), sulfur (S), chlorine (Cl), calcium (Ca), iron (Fe), and manganese (Mn). The composition is given in weight percent (wt %). 
     
       
         
           
               
             
               
                 TABLE 
               
             
            
               
                   
               
               
                 Elemental Composition of Black Powder 
               
            
           
           
               
               
               
            
               
                   
                 *Black Powder “as is” 
                 **Black Powder “heat treated” 
               
               
                 Element 
                 (wt %) 
                 (wt %) 
               
               
                   
               
            
           
           
               
               
               
            
               
                 C 
                 20.85 
                 0 
               
               
                 O 
                 29.29 
                 25.39 
               
               
                 Mg 
                 1.07 
                 1.08 
               
               
                 Si 
                 0.41 
                 0.48 
               
               
                 S 
                 1.88 
                 2.63 
               
               
                 Cl 
                 2.10 
                 1.53 
               
               
                 Ca 
                 1.23 
                 1.88 
               
               
                 Fe 
                 43.06 
                 65.7 
               
               
                 Mn 
                 non-detectable 
                 1.32 
               
               
                 Total 
                 100 
                 100 
               
               
                   
               
               
                 *as collected 
               
               
                 **after subjected to 500° C. for at least 3 hours 
               
            
           
         
       
     
     The sample of the heat-treated black powder was then subjected to additional heat treatment that was air calcination at about 775° C. for at least 4 hours. The crystal of the resulted powder as analyzed x-ray diffraction (XRD) was mainly hematite (Fe2O3) as shown in the XRD spectra in  FIG. 2 . 
       FIG. 2  is XRD spectra  200  of a sample of the black powder after the black powder was (1) heat treated at 500° C. for 3 hours and (2) subjected to calcination in air at 775° C. for 4 hours. The scattering angle (or diffraction angle) is 2-theta in degrees. The spectra  200  indicates phase identification of black powder after being heat treated first at 500° C. for several hours (at least 3 hours) and then at 775° C. for at least 4 hours. The heat treatment at both temperatures was performed under air. The heat treatment at 500° C. removes carbon. The heat treatment at 775° C. can be characterized as calcination. The x-ray diffraction of the calcined powder sample resulted in a pattern characterized by reflections (peaks in intensity) at certain positions. The symbols  202  note the peaks for the primary mineral in the sample of calcined black powder, which is hematite. The symbols  204  note the peaks for the secondary mineral in the sample, which is iron oxide Fe5O7. The symbols  202  locate the spectra of hematite, which is the most intense peaks over the other iron form. The spectra  200  indicates that a majority of the calcined black-powder sample is hematite. In particular, the spectra  200  indicates that at least 80 wt % of the air-calcined black powder is hematite. Calcined black powder as described herein may have at least 50 wt % hematite, at least 60 wt % hematite, at least 70 wt % hematite, at least 80 wt % hematite, or at least 90 wt % hematite. 
     Black powder as collected from a natural gas pipeline system may have primarily magnetite and hematite. The black powder may be heat treated (e.g., at 500° C.) to remove carbon (including carbon deposition) from the black powder. This heat-treated black powder may be subjected to calcination (e.g., at 775° C.). For the calcination performed in an inert atmosphere, the calcination may drive formation of magnetite. In contrast, for the calcination performed in an air atmosphere, the calcination may drive formation of hematite. As for minerals in the air-calcined black powder, hematite may approach 100 wt %. As for the overall composition of the air-calcined black powder, the hematite is at least 50 wt % and can be at least 80 wt % or at least 90 wt %. 
       FIG. 3  is a dry reformer  300  (including a dry reformer vessel  302 ) to convert hydrocarbon (e.g., CH4) in presence of CO2 and reforming catalyst  304  into syngas. The dry reformer  300  may be a dry reformer system. The dry reformer  300  or dry reformer vessel  302  may be characterized as a dry reformer reactor or dry reformer reactor vessel, respectively, for the dry reforming of hydrocarbon (e.g., CH4) to give syngas. A reforming catalyst  304  that is air-calcined black powder (e.g., see spectra  200  of  FIG. 2 ), as discussed above, is disposed in the dry reformer vessel  302 . The reforming catalyst  304  as calcined black powder may be black powder (e.g., collected from a natural-gas pipeline system) that is heat treated at a temperature of at least 500° C. for at least 3 hours and calcined at a temperature of at least 775° C. in presence of air for at least 4 hours. A majority of the calcined black powder is hematite. At least 50 wt % of the reforming catalyst  304  may be hematite. 
     The dry reformer  300  may be, for instance, a fixed-bed reactor or a fluidized bed reactor. The dry reformer vessel  302  may be a fixed-bed reactor vessel having the reforming catalyst  304  in a fixed bed. In implementations, the fixed-bed reactor vessel may be a multi-tubular fixed-bed reactor. The dry reformer vessel  302  may be a fluidized-bed reactor vessel that operates with a fluidized bed of the reforming catalyst  304 . 
     The operating temperature of the dry reformer  300  (the operating temperature in the dry reformer vessel  302 ) may be, for example, in the ranges of 500° C. to 1100° C., 500° C. to 1000° C., 500° C. to 900° C., at least 500° C., less than 1000° C., or less than 900° C. The dry reforming reaction may generally be endothermic. The dry reformer vessel  302  (dry reformer reactor vessel) may have a jacket for heat transfer and temperature control. In operation, a heat transfer fluid (heating medium) may flow through the jacket for temperature control of the dry reformer  300  including the dry reformer vessel  302 . Heat transfer may generally occur from the heat transfer fluid in the jacket to the dry reforming reaction mixture (process side of the dry reformer vessel  302 ). In other embodiments, electrical heaters may provide heat for the endothermic dry reforming reaction. The electrical heaters may be disposed in the dry reformer vessel  302  or on an external surface of the dry reformer vessel  302 . In yet other embodiments, the dry reformer vessel  302  may be disposed in a furnace (e.g., a direct fired heater) to receive heat from the furnace for the dry reforming reaction and for temperature control of the dry reformer  300 . Other configurations of heat transfer and temperature control of the dry reformer  300  are applicable. 
     The operating pressure in the dry reformer vessel  302  may be, for example, in the range of 1 bar to 28 bar, or less than 30 bar. In some implementations, the operating pressure may be greater than 30 bar to provide additional motive force for flow of the discharged syngas  310  to downstream processing. The downstream processing may include, for example, a Fischer-Tropsch (FT) system having a FT reactor vessel. The CO gas in the syngas  310  can be subjected to a water-gas shift reaction to obtain additional hydrogen. 
     In operation, the dry reformer vessel  302  may receive hydrocarbon  306  and carbon dioxide  308 . While the hydrocarbon  306  and the carbon dioxide  308  are depicted as introduced separately into the dry reformer vessel  302 , the hydrocarbon  306  and carbon dioxide  308  may be introduced together as combined feed to the dry reformer vessel  302 . The hydrocarbon  306  may generally include CH4. For example, the hydrocarbon  306  stream may be or include natural gas. In other examples, the hydrocarbon  306  includes CH4 but is not a natural-gas stream. The hydrocarbon  306  may be a process stream or waste stream having CH4. The hydrocarbon  306  may include CH4, propane, butane, and hydrocarbons having a greater number of carbons. The hydrocarbon  306  may include a mixture of hydrocarbons (e.g., C1 to C5), liquefied petroleum gas (LPG), and so on. Additional implementations of the hydrocarbon  306  (e.g., having CH4) are applicable. 
     The dry reforming of the hydrocarbon  306  via the CO2  308  and reforming catalyst  304  may give syngas  310  having H2 and CO. The dry reforming reaction via the catalyst  304  in the dry reformer vessel  302  may be represented by CH4+CO2→2H2+2CO. The molar ratio of H2 to CO in the syngas  310  based on the ideal thermodynamic equilibrium is 1:1 but in practice can be different than 1:1. Unreacted CH4 may discharge in the syngas  310  stream. In some implementations, unreacted CH4 may be separated from the discharged syngas  310  and recycled to the dry reformer vessel  302 . Moreover, the generated CO may be subjected to a water-gas shift reaction to obtain additional H2, as given by CO+H2O⇄CO2+H2. The water-gas shift reaction may be performed in the dry reformer vessel  302 . The reforming catalyst  304  may promote the water-gas shift reaction if implemented. The water-gas shift reaction may instead be implemented downstream. The discharged syngas  310  may be processed to implement the water-gas shift reaction downstream of the dry reformer vessel  302 . Utilization of the water-gas shift reaction, whether performed in the dry reformer vessel  302  or downstream of the dry reformer vessel  302 , may be beneficial to increase the molar ratio of H2/CO in the syngas  310  for downstream processing of the syngas  310 . The downstream processing may include, for example, an FT reactor or other processing. In certain implementations, the molar ratio of H2/CO may also be increased with the addition of supplemental H2 (e.g., from water electrolysis) to the discharged syngas  310 . 
     The dry reformer  300  system includes feed conduits for the hydrocarbon  306  and the carbon dioxide  308 , and a discharge conduit for the syngas  310 . The dry reformer vessel  302  may be, for example, stainless steel. The dry reformer  302  vessel has one or more inlets to receive the feeds (e.g.,  306 ,  308 ). The inlet(s) may be, for example, a nozzle having a flange or threaded (screwed) connection for coupling to a feed conduit conveying the feed to the dry reformer vessel  302 . The vessel  302  may have an outlet (e.g., a nozzle with a flanged or screwed connection) for the discharge of produced syngas  310  through a discharge conduit for distribution or downstream processing. The flow rate (e.g., volumetric rate, mass rate, or molar rate) of the feed  306 ,  308  may be controlled via flow control valve(s) (disposed along respective supply conduits) or by a mechanical compressor, or a combination thereof. The ratio (e.g., molar, volumetric, or mass ratio) of the hydrocarbon  306  (e.g., CH4 or natural gas) to the carbon dioxide  308  may be adjusted by modulating (e.g., via one or more control valves) at least one of the flow rates of the hydrocarbon  306  or the CO2  308 . Lastly, the present dry reforming may be a technique for conversion of CH4 and CO2 into syngas without the introduction of oxygen (O2) other than the less than 1 wt % that might be present as a residual or contaminant in the feed  306 . Thus, embodiments of the dry reforming do not include autothermal reforming (ATR). Further, embodiments of the dry reforming do not include steam reforming. However, the present treated black powder can be applicable as a reforming catalyst for steam reforming and ATR. 
     An embodiment is a dry reformer including a dry reformer vessel. The dry reformer vessel has at least one inlet to receive hydrocarbon (e.g., including methane) and CO2. The dry reformer vessel has a reforming catalyst disposed in the vessel to convert the methane and CO2 into syngas. The reforming catalyst includes or is calcined black powder. The reforming catalyst having or as the calcined black powder may be at least 50 wt % hematite. The dry reformer vessel has an outlet to discharge the syngas, wherein the syngas includes H2 and CO. The dry reformer vessel may be a fixed-bed reactor vessel having the reforming catalyst in a fixed bed. If so, the fixed-bed reactor vessel may be a multi-tubular fixed-bed reactor. The dry reformer vessel may be a fluidized-bed reactor vessel to operate with a fluidized bed of the reforming catalyst. 
       FIG. 4  is a method  400  of dry reforming hydrocarbon. The hydrocarbon may include CH4 and can be or include natural gas. The hydrocarbon may be a process stream or waste stream having CH4. The hydrocarbon may include CH4, propane, butane, and hydrocarbons having a greater number of carbons. 
     At block  402 , the method includes providing the hydrocarbon and CO2 to a dry reformer (e.g., to a dry reformer vessel). Reforming catalyst that is or includes treated black powder (processed black powder) is disposed in the dry reformer vessel. The treated black powder may be calcined black powder, as discussed. The reforming catalyst may be the present reforming catalyst as discussed above and as described in  FIG. 5 . 
     At block  404 , the method include dry reforming the hydrocarbon in the dry reformer via the reforming catalyst to generate H2 and CO. The dry reforming involves reacting the hydrocarbon with the CO2 via the treated black powder as the reforming catalyst. The method may include providing heat to the dry reformer (e.g., to the dry reformer vessel) for the dry reforming, wherein the reacting of the hydrocarbon with the CO2 is endothermic. Heat may be provided by external electrical heaters residing on the surface of the dry reformer vessel. Heat may be provided by disposing the dry reformer vessel in a furnace. Other techniques for providing heat to the dry reformer are applicable. 
     The reforming catalyst having amphoteric hematite may beneficially provide in the dry reforming for both methane cracking and CO2 dissociation. The amphoteric tendency of hematite may allow for both the dissociation of CO2 and cracking of methane. Oxidation of carbon species on the catalyst surface may also be realized in the dry reforming (of methane) reaction. The hematite being amphoteric (able to react both as a base and as an acid) may aid or promote methane cracking, disassociation of CO2, and oxidation of carbon species on its surface. 
     At block  406 , the method includes discharging the H2 and CO from the dry reformer (e.g., from the dry reformer vessel). The discharged stream having the H2 and CO may be labeled as syngas. The syngas may be sent to transportation or distribution. The syngas may be sent to downstream processing. In some embodiments, supplemental H2 may added to the syngas to increase the molar ratio of H2 to CO in the syngas. In certain embodiments, the water-gas shift reaction may be implemented in the dry reformer vessel or downstream of the dry reformer vessel to generate additional H2 to increase the molar ratio of H2 to CO in the syngas. 
     An embodiment is a method of dry reforming hydrocarbon, such as CH4. The method includes reacting the hydrocarbon with CO2 via reforming catalyst to generate syngas including H2 and CO. The reforming catalyst is or includes treated black powder that includes hematite. The hematite may be at least 50 wt % of the treated black powder. The treated black powder may be black powder from a natural gas pipeline and that is subjected to heat to give the treated black powder. The treated black powder may include black powder subjected to heat treatment at a temperature of at least 500° C. for at least 3 hours. The treated black powder may be black powder collected from a natural-gas pipeline system and that is subjected to heat in presence of air to give the treated black powder. The treated black powder may include calcined black powder. The treated black powder may include black powder subjected to heat treatment at a temperature of at least 775° C. in presence of air for at least 4 hours, and wherein this heat treatment includes air calcination of the black powder. The treated black powder may be or include collected black powder subjected to heat treatment at a temperature of at least 500° C. to remove carbon from the black powder and then subjected to air calcination at a temperature of at least 775° C. to give calcined black powder as the treated black powder. 
       FIG. 5  is a method  500  of preparing a reforming catalyst for dry reforming hydrocarbon (e.g., CH4). At block  502 , the method includes collecting black powder. Black powder may be collected as discussed above. The black powder may be collected (removed) from a natural-gas pipeline system. The natural-gas pipeline system may include a natural gas pipeline(s) including piping, mechanical compressors, filters, separators, etc. 
     At block  504 , the method includes receiving black powder. The black powder may be received at a location or facility to treat (e.g., heat treat, calcine, etc.) the black powder. The receiving of the black powder comprises may involve receiving the black powder collected from a natural-gas pipeline system. 
     At block  506 , the method includes applying heat to the black powder to remove carbon (e.g., carbon deposition) from the black powder. The black powder received may be placed, for example, in an industrial oven (e.g., industrial-scale heat regenerator) to heat the black powder. The application of the heat may involve applying the heat at a temperature of at least 500° C. for at least 3 hours to remove the carbon from the black powder. The applying of heat to the black powder to remove carbon from the black powder gives a heat-treated black powder. This applying of heat for the Example below was applied in the laboratory with a typical oven that was a muffle furnace. 
     At block  508 , the method includes calcining the black powder in presence of air to give calcined black powder as the reforming catalyst. The calcined black powder generally includes hematite. The calcining the black powder may involve calcining the heat-treated black powder (block  506 ) in the presence of air to give the calcined black powder as the reforming catalyst. The calcining may involve applying heat to the black powder in the presence of air at a temperature of at least 775° C. for at least 4 hours to give the calcined black powder as the reforming catalyst, wherein the hematite is at least 50 wt % of the calcined black powder. An example of equipment to subject the heat-treated black powder to calcination at about 775° C. or greater for at least four hours is a vessel in a furnace. In some implementations, the calciner is a steel cylinder having the black powder in an air atmosphere in the steel cylinder, and the steel cylinder rotates in a furnace to heat the black powder to about 775° C. or greater (in the air atmosphere inside the cylinder) for at least four hours. Calcination may be heating to high temperatures in air or oxygen. Calcination may be referred to as “firing” or “fired.” Calcining may remove unwanted volatiles from a material and convert a material into a more stable, durable, or harder state. In present embodiments, example conditions of the calcination include calcining the black powder in air at a temperature in a range of 700° C. to 800° C. for at least 4 hours. The main compound (e.g., up to 90 wt %, or at least 90 wt %) of the air-calcined black powder may be Fe2O3. The remainder of the air-calcined black powder may include small amounts or trace elements of other oxides, such as other iron oxides or silicon oxide (SiO2). In some implementations, SiO2 may dominate the remainder of air-calcined black powder. The mineral SiO2 is not listed on  FIG. 2  because SiO2 was below the detection limit of the used XRD device. However, the SiO2 present in the  FIG. 2  sample was detected by x-ray fluorescence (XRF) analysis. 
     At block  510 , the method includes supplying the calcined black powder formed in block  508  as the reforming catalyst for dry reforming of methane. The calcined powder may be removed from the calcination equipment (e.g., vessel) and transported to a facility that dry reforms methane. The calcined black powder as reforming catalyst may be placed into a dry-reformer reactor vessel. 
     An embodiment is of preparing a reforming catalyst for dry reforming methane. The method includes receiving black powder and applying heat to the black powder to give heat-treated black powder. The applying of heat to the black powder may involve applying the heat at a temperature of at least 500° C. to give the heat-treated black powder. The method includes applying heat to the heat-treated black powder in presence of air to give a calcined black powder, wherein a majority of the calcined black powder is hematite. The applying of heat to the heat-treated black powder may involve applying the heat to the heat-treated black powder at a temperature of at least 775° C. in the presence of air to give the calcined black powder. The reforming catalyst may be or include the calcined black powder. 
     Example 
     In the laboratory, the performance of the present heat-treated/calcined black powder (primarily hematite) to generate hydrogen in dry reforming of methane was compared to performance of a conventional reforming catalyst having the universal basic catalyst substrate of MgO to generate hydrogen in dry reforming of methane. The MgO is both a support and the active catalyst. The dry reforming performance of the present treated black powder versus the dry reforming performance of the conventional MgO were compared at the same conditions of dry reforming. The dry reforming conditions included 750° C., 14 bar, and a gas hour space velocity (GHSV) of 1477 h −1 . 
       FIG. 6  depicts results of the Example comparison, which show a better performance by the heat-treated/calcined black powder having primarily Fe2O3 (amphoteric) as compared to the non-amphoteric (solely basic) MgO.  FIG. 6  is a plot of the percent (mol %) of H2 in the effluent over time (hours). The time was the experiment time of the dry reforming in the laboratory. The curve  602  is the mol % H2 in the effluent with the dry reforming catalyst as the heat-treated/calcined black powder. The curve  604  is the mol % H2 in the effluent with the dry reforming catalyst as the MgO. 
     The dry reforming in the Example laboratory evaluation was performed in a Microactivity Effi microreactor (compact reactor) system available from PID Eng &amp; Tech (Madrid, Spain) having Micromeritics Instrument Corp. as parent corporation. The microreactor is configured for operation at pressures up to 100 bars. In the Example, 3 milliliters (ml) of the prepared black powder was loaded on the microreactor with a diameter of 9 millimeter (mm) Hastelloy tube and placed inside an electrical furnace. The prepared black powder ( FIG. 2 ) was the black powder subjected to heat at 500° C. for 3 hours and then calcined at 775° C. for 4 hours. In the electrical furnace, the prepared black powder was reduced with H2 and nitrogen (N2) at 750° C. for 6 hours before the reforming reaction was started. This reduction of the catalyst may make the catalyst more active for the dry reforming reaction. Then, a mixture of CH4, CO2, and N2 were fed to the microreactor. The feed molar ratio of CH4 to CO2 was 1. The N2 was fed into the microreactor in order to give the GHSV of 1477 h −1 . The treated black-powder catalyst was gradually pressurized and tested at 14 bar and 750° C. while feeding the mixture of CH4, CO2, and N2. The same was performed for the MgO (3 ml) catalyst support at the same conditions as well. Testing for each was performed for about 6 hours. The produced gas was analyzed by the gas chromatography (GC, Agilent 7890B) equipped with a thermal conductivity detector (TCD) and a flame ionization detector (FID). Before analysis, water in the gas was removed with a liquid/gas separator and a moisture trap. The concentrations of H2 were determined with the TCD. The mol composition from the GC was converted quantitatively based on the amount of N2 in the produced gas. 
     The Fe2O3 has an amphoteric characteristic (acidic-basic), which may trigger its use as a catalyst in dry reforming. Because the Fe2O3 can provide basic sites for CO2 dissociation as well as acidic sites for methane cracking, the need for adding or impregnating precious or non-precious metal typically utilized with dry reforming catalyst may be avoided in present implementations. Behavior of different support types of reforming catalysts in the dry reforming of methane into syngas may be compared. Amphoteric support catalysts, such as catalyst that is Fe2O3 or the present treated (processed) black powder having primarily Fe2O3, the catalyst may provide for (allows) CH4 cracking and CO2 dissociation that may occur contemporaneously or simultaneously in the dry reforming. In contrast, acidic support catalysts (e.g., silicon oxide or SiO2) may provide for (allow) CH4 cracking but generally not CO2 dissociation in the dry reforming. Basic support catalysts (e.g., MgO) may provide for (allows) CO2 dissociation but generally not CH4 cracking in the dry reforming. Iron groups consisting of Ni, Co, and Fe possess a high activity toward hydrocarbon cracking, with Fe being the lowest activity among the group. However, the Fe2O3 being amphoteric may avoid the need to add or impregnate precious or non-precious metals to the catalyst. The air-calcined black powder as a catalyst for dry reforming process may be advantageous because it mainly consists of the amphoteric (acidic and basic) Fe2O3, which may generally allow for the simultaneous occurrence of methane cracking and CO2 dissociation without the need to add/impregnate precious or non-precious metals nor the need to have specific basic sites on the substrate. 
     An embodiment is a reforming catalyst for dry reforming CH4 with CO2. The reforming catalyst includes or is calcined black powder that is black powder heat treated at a temperature of at least 500° C. for at least 3 hours and calcined at a temperature of at least 775° C. in presence of air for at least 4 hours. The black powder is from a natural gas pipeline. A majority of the calcined black powder is hematite. The hematite may be both a support and active portion of the reforming catalyst. The hematite being amphoteric may advance cracking of the CH4 and dissociation of the CO2. 
     Another embodiment is a reforming catalyst for dry reforming CH4 with CO2. The reforming catalyst has at least 70 wt % (or at least 80 wt %) of hematite. The hematite is both a support and catalytic active portion of the reforming catalyst. The hematite being amphoteric advances both cracking of the CH4 and dissociation of the CO2 in dry reforming of the methane. The reforming catalyst may be or include calcined black powder having the hematite. The calcined black powder is black powder heat treated at a temperature of at least 500° C. for at least 3 hours and calcined at a temperature of at least 775° C. in presence of air for at least 4 hours. The black powder is from a natural gas pipeline. 
     A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure.