TH22131B - Methods for the production of olefins from lower alkanes. By oxidative dehydrogenation - Google Patents

Abstract

The invention DC60 provides a method for the production of olefins such as ethylene and propylene from lower alkanes, ie methen, ethane and / or propane. By oxidative Dehydrogenation at Pressure raised Separate purified, selectively return olefins From feeder lower alkanes Unchanged and reactive by-products By means of stacking separation, for example sorption separation at Use of silver nitrate As a complexing agent, using a catalyst that provides Selection condition High for oxidative Dehydrogenation of lower alkanes to olefins at elevated pressures, like a rare-earth catalyst that does not Quantitative The invention provides a method for producing olefins such as ethylene and propylene from lower alkanes, ie methen, ethane and / or propane. By oxidative Dehydrogenation at Pressure raised Separate purified, selectively return olefins From feeder lower alkanes That have not changed and by-products have reacted By means of stacking separation, for example sorption separation at Use of silver nitrate As a complexing agent, using a catalyst that gives Selection condition High for oxidative The dehydrogenation of lower alkanes becomes an olefin at elevated pressure, like a rare-earth, oxidized-carbonate catalyst without Quantitative

Claims (1)

1. a method for producing olefins from one or more lower alkanes. By oxidative Dehydrogenation This includes: (1) provision of at least one lower alkane (2) supply of oxygen (3) replacement of part of the lower alkane by reaction process. Sydative dehydration A genation that uses a catalyst to produce unchanged lower alkanes with At least one produces Olefins, at least one by-product, alkanes and water at which pressure acts It is at least approximately 50 psi and can form olefin and by-products. Alkanes from lower alkanes containing The combined selection condition was at least approximately 40 percent: (4) dehydration from unchanged lower alkanes (5) purified separation of at least one olefin product. From the unspecified lower alkanes Change by using isolation too. Complexification using one or more auxiliaries For selective separation of olefi Olefins and non-membrane separation and (6) reuse after most of the lower (4) and (5) procedures. Non-alkanes Change which at least one produces By-products have alkanes to the oxidative dehydrogenation process of the procedure (3) 2. Method of claim No. 1, where the lower alkanes It is one of methane and ethane. 3. Method of claim number 1, where the separation by complexification makes use of the bond complexes (formulas) to selectively extract the olefinol. Except Non-Olefin 4. Clause 1 method, where the reaction temperature is less than approx 700 ํ 5. Method of claim 1, where the pressure acts. It ranges from approximately 100 psi to approximately 400 psi. 6. Claim Method 1, where the mole ratio of olefin to alkane by-products is at least step (3). Approximately 1/1 7. Clause 2, where at least one olefin product is ethylene and at least one by-products alkane is ethane. Holds the right to Article 1, where the oxidative dehydrogenation reaction process is used Fixed base reaction device or reaction device Fluidized bases with a joint infusion of lower alkanes and oxygen 9. Method of claim No. 1, where the oxidative dehydrogenation process using the system Flowing fluidized base reaction in which the lower alkane feeder comes into contact with the oxidized catalyst in the riser. In order to accelerate the reaction that Reduced and oxidized. Catalysts that are reduced from the riser using air or oxygen in the purifier back. Return of the fluidized base 1 0. Method of claim 1, where at least most of the oxidized dehydrogenate of at least one alkane by-product was introduced. Reuse To cause at least one Olefin Products 1 1. Method of Clause 1, where it is further combined with CO2 separation. Leaving the unchanged lower alkanes before Procedure (6) 1 2. Clause 1 Clause 1, which is further incorporated by adding the Lower Alkane. Alkanes that have not changed Where at least one by-product alkane goes to the methane gas transmission system 1 3. Method of claim 1, where the complexization separation It is a selective bioavailability and a selective absorbing complex of ethylene and propylene, without significantly higher olefins (higher olefins) absorption 1 4. The method of claim 1, where complex separation It is a sorption agent and a complexing agent containing silver ions (I) 1 5. Method of claim 14, where the complexing agent is silver ashyrene. Nitrate 1 6. Method of claim 1, where the catalyst showing the selection condition for olefin products and by-products produces alkanes at the reaction pressure. Used for oxidation Dehydrogenation Higher than the catalyst Reactions or reactants The catalyst is expressed at a range of approximate atmospheric pressure to approximately 25 psig 1 7. Method of claim 1, where the catalyst can dehine. Oxidative rogenate at least one by-product alkane to form at least one olefin 1 8. Method of claim 1, where the catalyst is One kind of catalyst Promoted metal transisun oxide and catalyst Promoted Rare Erith Oxide 1 9. Method of claim Article 18, where the catalyst is selected. From the group consisting of Mn / Na2WO4, Sr / La2O3, and Sr / Sm2O3 2 0. Method of claim 1, where the catalyst was selected from the group containing Rare Earth Oxycarbonate Catalyst, Rare Earth Hydroxycarbonate Reaction Accelerator, and Rare Earth Oxygen Catalyst Carbonate 2 1. Method of Clause 20, where the catalyst, which consists of a non-quantitative rare earth oxidized carbonate with the formula MxCyOz, has Disordered and / or depleted structures, where M is at least one rare earth element. Selected from a group consisting of La, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, and Tm; X = 2; Z = 3 + AY; A less than approx 1.8; And Y is the number of carbon atoms in the oxycarbonate, and the catalyst mentioned above, when used for oxidative dehydrogenation. At the above pressure of approximately 100 psig, at least approximately 40% of the selection condition was obtained for olefin and by-alkanes 2 by-products. Rights item 1, which is included further With at least the next change of sequence One olefin product The purified separation was returned in step (5) to at least one olefin derivative whose production speed of at least one olefin at Said that Similarly, the arrangement speed of at least one of the aforementioned olefins is significantly required to produce At least one derivative The said olefins At the speed Produce desired And select at least one olefin derivative from the group consisting of polyolefin, ethylene-propylene rubber, ethylene oxide, ethylene glycol, ethanol. 2. Methods for the production of ethylene and / or propylene, from at least one lower alkane. By oxidative dehydrogenation Which includes: (1) providing at least one lower alkanes; (2) providing the source of oxygen; (3) Replacement of part of lower alkanes by catalytic oxidative dehydrogenation process. Reaction Rare Earth Oxycarbonate To produce lower alkanes Unchanged containing at least ethylene and / or propylene, at least one by-product, alkane and / or at least one higher olefin and water. In which the reaction pressure is at least approximately 75 psi and produces olefins and by-products. Lower alkanes containing The combined selection condition is at least approximately 40% and the mole ratio of olefins to alkanes by-products is at least approximately 1/1; (4). Unchanged alkanes; (5) pure separation, return ethylene And / or polypropylene from Lower L. The unchanged Ken By using suction separation Permeate an anhydrous complex using one or more auxiliaries containing silver ions (I) for selective separation of ethylene and / or propylene from Higher olefins and non-olefins, and which are not membrane separation; And (6) recycled after procedures (4) and (5), most of the unchanged lower alkanes containing at least one by-product alkane. And / or higher olefins to the oxidative dehydrogenation process of the procedure (3) 2 4. Clause 23, where the Lower A Methane 2 5. Methods for the production of olefins from At least one lower alkane by oxidative Dehydrogenation, which reduces or eliminates the recycling of lower alkanes that Have not changed with By-products of action which include: (1) providing at least one lower alkane; (2) Providing oxygen source; (3) Replacement of part of lower alkanes by oxidative dehydro reaction process. A genation using a catalyst whose reaction pressure is at least about 50 psi to produce unrefined lower alkanes. Replace containing at least one olefin product, at least one combustible byproduct and water in it; (4) Dewatering of unchanged methane; (5) Purification returned at least one olefin product. From the unspecified lower alkanes Changed by using separation by making it A complex that uses one or more auxiliaries to be selective separation of olefins from non-olefins and which is not membrane separation and (6) addition after Steps (4) and (5) most of the lower alkanes. That has not changed, which has At least one by-product of the combustion is the methane gas transportation system 2. 6. Method of claim 25, where at least one lower alkane in step (1) is natural gas processed. Then supplied from the transportation system Natural gas, and the phase gas methane transportation system (6) is the natural gas transmission system of the procedure (1) 2 7. Method of claim 26, in which such natural gas transportation system is a pipe. Transmission of natural gas 2. 8. Method of claim 25, which is further incorporated with carbon dioxide separation. Leave the unchanged lower alkanes before Procedure (6) 2 9. Clause 1, where the unchanged lower alkanes will not change. Which will contain at least one By-products, the alkanes of the step (6) are gaseous discharges. Which has heating value 3 0. Method of claim 1, where the complexization is absorption and substance separation. Helps to form a complex containing 3 copper ions (I) 1. Method of claim No. 1, where complex separation Is also a separation Assimilation using a mixture of a complexing agent containing silver and copper salts