A system and method for preparing propylene by catalytic dehydration of methanol

Abstract

The present invention relates to a system and a method for preparing propylene through catalytic dehydration of methanol, the system comprising a dehydration reactor, a catalyst regenerator, a heating furnace, a heat exchanger, and a separating unit, an inlet of the dehydration reactor being connected to the heating furnace and one of the heat exchange channels of the heat exchanger to form a raw material channel, an outlet of the dehydration reactor being connected to the other heat exchange channel of the heat exchanger and the separating unit to form a product channel, and the catalyst regenerator being connected to the interior of the dehydration reactor to form a catalyst recycling loop; after reaction, a reaction material is discharged in the form of a product; the catalyst is internally arranged in the dehydration reactor, the catalyst entering the catalyst regenerator to be regenerated to recover activity, and then being returned to the interior of the dehydration reactor to be reused. Compared to the prior art, the present invention uses a ZSM-5 molecular sieve in a dehydration reactor of a fluidised bed structure to implement a methanol catalytic dehydration reaction, the unwanted high carbon olefin being fully recycled and converted into propylene, and a small amount of ethylene by-product being simultaneously produced. Therefore, the system and method of the present invention have high propylene selectivity.

Description

technical field [0001] The invention relates to a propylene production system and method, in particular to a system and method for preparing propylene by catalytic dehydration of methanol. Background technique [0002] Low-carbon olefins, especially ethylene and propylene, are important chemical basic raw materials. With the development of industrial economy in various countries, their demand is increasing. At present, the main production methods of light olefins are the by-products of naphtha steam cracking and catalytic cracking units. However, global oil reserves are limited, unevenly distributed, and prices fluctuate greatly. Therefore, the development of non-petroleum propylene production processes has very important strategic significance for the diversification of olefin raw materials. [0003] Methanol catalytic dehydration to olefins technology is the most competitive non-petroleum route, including three steps: (1) synthesis gas from natural gas, coal or biomass, (...

AI Technical Summary

Problems solved by technology

[0010] In the existing technology, due to the large heat release of multi-stage fixed-bed reactors, the concentration of methanol in each stage is only 5-8wt%, the reaction rate is slow, and the multi-stage structure further increases the residence time of olefins, so the selection of total low-carbon olefins Sex is not high

At the same time, frequent (every 600-1000 hours) reaction / regeneration switching increases the difficulty of operation and equipment maintenance

In the fluidized bed route, the coking rate of SAPO-34 is fast, and the coking loss of methanol is large, which increases the energy consumption of catalyst regeneration, and at the same time, the selectivity of ethylene in the product is relatively high

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