Phosphorus and rare earth synergistically modified ZSM-5 and method for increasing propylene yield through catalytic cracking by using phosphorus and rare earth synergistically modified ZSM-5

A ZSM-5, synergistic modification technology, applied in chemical instruments and methods, catalysts, hydrocarbon cracking and production of hydrocarbons, etc., can solve the problems of less surface voids, poor composite effect, poor activity, etc.

Inactive Publication Date: 2020-02-21
YANAN UNIV
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  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0002] At present, in the production of propylene, ZSM-5 molecular sieve is one of the important catalysts to improve the production efficiency and quality of propylene, whether it is directly using raw material hydrocarbon oil or based on raw materials such as methanol for cracking, decomposition and conversion to produce propylene. In actual use, it is found that the currently used ZSM-5 molecular sieve is often in the traditional ZSM-5 molecular sieve structure, although it can meet the needs of use to a certain extent, but on the one hand, there is poor activity of ZSM-5 molecular sieve, short service life, and ZSM-5 molecular sieve has less surface voids and poor selectivity to propylene. On the other hand, the currently used ZSM-5 molecular sieve also has poor recombination with the catalytic cracking main catalyst produced by propylene, which seriously affects the catalytic cracking main catalyst. Catalytic Cracking Efficiency

Method used

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  • Phosphorus and rare earth synergistically modified ZSM-5 and method for increasing propylene yield through catalytic cracking by using phosphorus and rare earth synergistically modified ZSM-5
  • Phosphorus and rare earth synergistically modified ZSM-5 and method for increasing propylene yield through catalytic cracking by using phosphorus and rare earth synergistically modified ZSM-5

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0023] like figure 1 and 2 As shown, a phosphorus and rare earth synergistically modified ZSM-5 is composed of the following mass percentage substances: bentonite 1%, titanium dioxide 3%, calcium oxide 3%, zinc oxide 2.5%, copper oxide 1.1%, toughening modifier 1%, coupling agent 1.1%, sepiolite 5.5%, ethyl silicate 4%, hollow glass microspheres 3%, aluminum ash 35%, quartz sand 11%, sodium carbonate 2%, phosphorus pentoxide 3.5%, Light rare earth 1.1%, the balance is silica sol.

[0024] Wherein, the bentonite, titanium dioxide, calcium oxide, zinc oxide, copper oxide, and sepiolite all have a solid powder structure of 100 mesh; the particle size of the hollow glass microspheres is 10 microns.

[0025] Meanwhile, the coupling agent is a silane coupling agent.

[0026] Emphatically, the preparation process of the phosphorus and rare earth synergistically modified ZSM-5 includes the following steps:

[0027] The first step is to mix the materials. First, bentonite, titanium...

Embodiment 2

[0037] like figure 1 and 2As shown, a phosphorus and rare earth synergistically modified ZSM-5 is composed of the following mass percentage substances: bentonite 5%, titanium dioxide 5%, calcium oxide 5%, zinc oxide 3.8%, copper oxide 2.7%, toughening modifier 2.5%, coupling agent 2.1%, sepiolite 15%, ethyl silicate 6%, hollow glass microspheres 9%, aluminum ash 20%, quartz sand 6%, sodium carbonate 5%, phosphorus pentoxide 5.5%, Light rare earth 4.8%, the balance is silica sol.

[0038] Wherein, the bentonite, titanium dioxide, calcium oxide, zinc oxide, copper oxide, and sepiolite are all 500-mesh solid powder structures; the particle diameter of the hollow glass microspheres is 100 microns.

[0039] Meanwhile, the coupling agent is a titanate coupling agent.

[0040] Emphatically, the preparation process of the phosphorus and rare earth synergistically modified ZSM-5 includes the following steps:

[0041] The first step is to mix the materials. First, bentonite, titaniu...

Embodiment 3

[0051] like figure 1 and 2 As shown, a phosphorus and rare earth synergistically modified ZSM-5, said phosphorus and rare earth synergistically modified ZSM-5 is composed of the following mass percentage substances: 2% bentonite, 4% titanium dioxide, 4% calcium oxide, 3% zinc oxide %, copper oxide 1.5%, toughening modifier 1.8%, coupling agent 1.9%, sepiolite 7.5%, ethyl silicate 5%, hollow glass microspheres 6%, aluminum ash 25%, quartz sand 9% , sodium carbonate 4%, phosphorus pentoxide 4.5%, light rare earth 2.8%, and the balance is silica sol.

[0052] Further, the bentonite, titanium dioxide, calcium oxide, zinc oxide, copper oxide, and sepiolite all have a solid powder structure of 100-500 mesh; the particle diameter of the hollow glass microspheres is 10-100 microns.

[0053] Further, the coupling agent is any one of silane coupling agent and titanate coupling agent.

[0054] Further, the preparation process of the phosphorus and rare earth synergistically modified Z...

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Abstract

The invention relates to phosphorus and rare earth synergistically modified ZSM-5. The phosphorus and rare earth synergistically modified ZSM-5 is composed of the following substances in percentages by mass: 1% to 5% of bentonite, 3% to 5% of titanium dioxide, 3% to 5% of calcium oxide, 2.5% to 3.8% of zinc oxide, 1.1% to 2.7% of copper oxide, 1% to 2.5% of a toughening modifier, 1.1% to 2.1% of acoupling agent, 5.5% to 15% of sepiolite, 4% to 6% of ethyl silicate, 3% to 9% of hollow glass beads, 20% to 35% of aluminum ash, 6% to 11% of quartz sand, 2% to 5% of sodium carbonate, 3.5% to 5.5%of phosphorus pentoxide and 1.1% to 4.8% of light rare earth, with the balance being a silica sol. The method for increasing propylene yield by catalysis comprises two steps, i.e., a step of raw material pretreatment and a step of material mixing. The phosphorus and rare earth synergistically modified ZSM-5 provided by the invention effectively improves the hydrothermal stability of a ZSM-5 molecular sieve, has high activity, long service life and good propylene selectivity, has good compounding effect with a catalytic cracking main catalyst in propylene production, can greatly improve the catalytic cracking conversion efficiency of raw materials, greatly increases the production efficiency of liquefied gas and the content of propylene in the liquefied gas, thereby achieving the purpose ofimproving the efficiency and quality of propylene production operation.

Description

technical field [0001] The invention relates to a phosphorus and rare earth synergistically modified ZSM-5 and a method for increasing the production of propylene by catalytic cracking, belonging to the technical field of propylene production. Background technique [0002] At present, in the production of propylene, ZSM-5 molecular sieve is one of the important catalysts to improve the production efficiency and quality of propylene, whether it is directly using raw material hydrocarbon oil or based on raw materials such as methanol for cracking, decomposition and conversion to produce propylene. In actual use, it is found that the currently used ZSM-5 molecular sieve is often in the traditional ZSM-5 molecular sieve structure, although it can meet the needs of use to a certain extent, but on the one hand, there is poor activity of ZSM-5 molecular sieve, short service life, and ZSM-5 molecular sieve has less surface voids and poor selectivity to propylene. On the other hand, ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B01J29/40C07C4/06C07C11/06
CPCB01J29/405C07C4/06B01J2229/18C07C2529/40Y02P20/52
Inventor 李雪礼侯硕旻张琰图牛保明路瑞玲王亚斌张哲豪金君蔺军兵
Owner YANAN UNIV
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