Abstract: A method for cleaning and rejuvenating an at least partially spent de-NOx catalyst comprising a porous ceramic metal oxide material containing a vanadium oxide and coated on a metal support by cleaning the catalyst with an oxalic acid solution and by contacting the catalyst with a vanadium compound solution.

Abstract: A method for removing carbon oxides from a hydrogen stream containing more than 0.1 ppmv of carbon monoxide, carbon dioxide or a mixture thereof, by charging the hydrogen with a hydrocarbonaceous stream containing a minor amount of aromatics to an aromatics saturation zone; saturating at least a portion of the aromatics and methanating at least a major portion of the carbon oxide to produce a reduced aromatics content hydrocarbonaceous stream and a reduced carbon oxide content hydrogen stream; and recovering the reduced aromatics content hydrocarbonaceous stream and the reduced carbon oxide content hydrogen stream. The hydrogen may optionally be dried or further purified.

Abstract: A method for isomerizing at least a portion of a butane stream using a hydrogen stream containing more than 0.1 ppmv of carbon monoxide, carbon dioxide or a mixture thereof, the method comprising: charging the hydrogen stream containing at least 0.1 ppmv of at least one carbon oxide to a aromatics saturation zone to produce a reduced carbon oxide content hydrogen stream; recovering the reduced carbon oxide content hydrogen stream; drying at least a portion of the reduced carbon oxide content hydrogen stream to produce a dried reduced carbon oxide content hydrogen stream; charging at least a portion of the dried reduced carbon oxide content hydrogen stream to a butane isomerization zone; charging the butane stream to the butane isomerization zone; and, isomerizing at least a portion of the butane to produce an isobutane stream.

Abstract: A method for reducing the benzene content and isomerizing at least a portion of a C.sub.5 /C.sub.6 paraffinic stream using a hydrogen stream containing more than 0.1 ppmv of carbon monoxide, carbon dioxide or a mixture thereof, the method comprising: charging a C.sub.5 /C.sub.6 paraffin stream containing benzene to a benzene saturation zone; charging a hydrogen stream containing at least 0.1 ppmv of at least one carbon oxide to the benzene saturation zone; saturating at least a major portion of the benzene and methanating at least a major portion of the carbon oxide present in the benzene saturation zone to produce a reduced benzene content C.sub.5 and C.sub.6 paraffinic stream and a reduced carbon oxide content hydrogen stream; recovering the reduced benzene content C.sub.5 and C.sub.

Abstract: A method of treating spent selective catalytic reduction (SCR) catalyst is provided, which method comprises contacting the spent catalyst with a solution comprising a SCR catalyst metal salt, preferably a vanadium salt, and heating the catalyst contacted with the metal salt solution at a calcination temperature in the presence of oxygen. Preferably, after treatment with the metal salt solution, the catalyst is dried with air for at least about 10 seconds and heated to a temperature in the range of about 130.degree. F. to about 170.degree. F. for a period of about 30 minutes to about 90 minutes before heating to the calcination temperature.

Abstract: An improved process minimizing the detrimental effects caused by inadvertently contacting a high sulfur, high water-containing hydrocarbon feedstock with a platinum group metal, halogen-containing catalyst is disclosed. The present process involves discontinuing the high sulfur, high water-containing feedstock-catalyst contacting while passing hydrogen over the catalyst. The catalyst halogen concentration is maintained or increased by the addition of halogen component, for example, during the hydrogen pass through. Once the sulfur contamination has been removed from the catalyst, normal hydrocarbon reforming is resumed.

Abstract: An improved hydrocarbon reforming process comprising:1. contacting a hydrocarbon feed with a platinum group metal, rhenium-containing catalyst in the presence of hydrogen in at least one reaction zone at a temperature in the range of about 500.degree. F. to about 650.degree. F. for a time sufficient to improve the catalytic activity stability of the catalyst; and thereafter,2. contacting the hydrocarbon chargestock with the catalyst in the presence of hydrogen at hydrocarbon reforming conditions including a higher temperature than the temperature at which step (1) occurred.

Abstract: A process for reducing the sulfur content of hydrocarbon material by contacting, e.g., heating, the sulfur-containing hydrocarbon material with at least one hydrocarbon hydrogen donor component capable of transferring hydrogen under conditions such that hydrogen transfer from said component to the sulfur-containing hydrocarbon material occurs to form hydrogen sulfide, oxidizing at least a portion of the remaining sulfur impurities contained in the hydrocarbon material and recovering a hydrocarbon material of reduced sulfur content.

Abstract: A process for reducing the sulfur content of hydrocarbon material by oxidizing the sulfur impurities contained in the hydrocarbon material, contacting the oxidized sulfur-containing hydrocarbon material with at least one of certain metal containing components at conditions to form a metal, sulfur-containing compound and recovering a hydrocarbon material of reduced sulfur content.