METHOD FOR PREPARING A LIGHT OLEFIN WITH AN OXYGEN-CONTAINING COMPOUND

摘要

A method for improving the light olefin yield in the process of preparation of a light olefin using an oxygen-containing compound, more specifically, in which, a multi-stage dense phase fluidized bed comprising k secondary pre-carbon deposition zones (k≧1) and n secondary reaction zones (n≧1) is used as a reactor, and a multi-stage dense phase fluidized bed regenerator comprising in secondary regeneration zones (m≧2) is used as a main equipment, and by re-refining hydrocarbons with four or more carbons obtained in the separation section, or adding naphtha, gasoline, condensate oil, light diesel oil, hydrogenation tail oil or kerosene in the reaction zone, the method primarily solves the problems in the prior art of the uniformity of carbon deposition amount and the carbon content of the catalyst being difficult to control, and the light olefin yield being low.

主权项

1. A method for preparing a light olefin using an oxygen-containing compound, comprising the following steps:
step a) in which a hydrocarbon with four or more carbons is introduced from k feeding branch lines of pre-carbon deposition zone in parallel into k secondary pre-carbon deposition zones in a dense phase fluidized bed reactor, and is brought into contact with a completely regenerated and/or fresh catalyst, so as to be converted into a light olefin product-containing stream, while forming a pre-carbon deposited catalyst; wherein the catalyst is passed sequentially through 1st to kth secondary pre-carbon deposition zones, with carbon content thereof increasing gradually; wherein the dense phase fluidized bed reactor is divided by a material flow controller into a pre-carbon deposition zone and a reaction zone; and wherein the pre-carbon deposition zone of the dense phase fluidized bed reactor is divided by a material flow controller into k secondary pre-carbon deposition zones, with 1st to kth secondary pre-carbon deposition zones being connected in sequence; step b) in which a raw material comprising the oxygen-containing compound is introduced from n feeding branch lines of reaction zone in parallel into n secondary reaction zones of the dense phase fluidized bed reactor, and is brought into contact with the pre-carbon deposited catalyst, to generate a light olefin product-containing stream and a spent catalyst; wherein the pre-carbon deposited catalyst flowed out from the kth secondary pre-carbon deposition zone is passed sequentially through 1st to nth secondary reaction zones, with carbon content thereof increasing gradually; wherein the reaction zone of the dense phase fluidized bed reactor is divided by a material flow controller into n secondary reaction zones, with 1st to nth secondary reaction zones being connected in sequence, and the 1st secondary reaction zone being connected to the downstream of the kth secondary pre-carbon deposition zone; step c) in which the light olefin product-containing stream flowed out from the pre-carbon deposition zone and the reaction zone is separated from the entrained spent catalyst; the isolated spent catalyst is passed into the nth secondary reaction zone; and the light olefin product-containing stream is passed into a product separation section, in which the light olefin product is obtained by isolation and purification, and the hydrocarbon byproduct with four or more carbons obtained from the separation section is returned back to the pre-carbon deposition zone in the dense phase fluidized bed reactor; and step d) in which the spent catalyst flowed out from the nth secondary reaction zone, after being stripped and lifted, is passed into a dense phase fluidized bed regenerator for regeneration; said spent catalyst is passed sequentially through 1st to mth secondary regeneration zones; a regeneration medium is introduced in parallel from m feeding branch lines of regeneration zone into the 1st to mth secondary regeneration zones, and the spent catalyst is brought into contact with the regeneration medium, with the carbon content thereof decreasing gradually; the catalyst after the completion of regeneration is returned back to the 1st secondary pre-carbon deposition zone via stripping and lifting; wherein the dense phase fluidized bed regenerator is divided by a material flow controller into m secondary regeneration zones, and 1st to mth secondary regeneration zones are connected in sequence; wherein k≧1, n≧1, and m≧2.