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CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst reactivating method

The technology of a palladium catalyst and an oxidizing couple is applied in the field of regeneration after the deactivation of the catalyst for the synthesis of dimethyl oxalate by CO gas phase oxidative coupling, and can solve the problems of inability to remove impurities, permanent deactivation of the catalyst, high processing cost and the like, Achieve the effect of easy industrial operation, good safety and excellent activity index

Active Publication Date: 2017-03-29
FUJIAN INST OF RES ON THE STRUCTURE OF MATTER CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

For example, the patent CN103191759A discloses a regeneration method for Pd / C catalysts. The deactivated catalyst is dried and oxidized at a temperature of 50-140°C in an air atmosphere. The disadvantage is that the lower calcination temperature cannot adsorb or The generated impurities are completely removed
Patent CN104190441A discloses an online regeneration method of deactivated palladium catalyst in the coal-to-ethylene glycol process. The deactivated catalyst is activated and regenerated in a fixed-bed reactor under high-temperature water vapor, oxygen, hydrogen and other atmospheres. The existing disadvantages Higher temperature steam treatment can easily lead to permanent deactivation of the catalyst
Patent 03122844.5 discloses a palladium catalyst regeneration method, extracting the deactivated catalyst in carbon dioxide under supercritical conditions to remove the organic impurities adsorbed on the palladium catalyst, so that the catalyst can be regenerated. The disadvantage is that harsh supercritical conditions require higher processing costs
[0006] At present, there are few reports on the regeneration method after deactivation of CO gas-phase oxidative coupling synthesis dimethyl oxalate catalyst in the coal-to-ethylene glycol synthesis process. Therefore, at the time of the rapid development of coal-to-ethylene glycol technology, a new The efficient palladium catalyst regeneration method ensures the efficient recycling of precious metals and has long-term significance for reducing the cost of the entire coal-to-ethylene glycol industrialization

Method used

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  • CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst reactivating method
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  • CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst reactivating method

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Effect test

Embodiment 1

[0030] (1) Catalyst regeneration

[0031] 15g of deactivated Pd / a-Al 2 o 3 The catalyst is put into a muffle furnace and roasted at 600°C for 4 hours, and the calcined catalyst is added to a hydrochloric acid solution with a mass fraction of 5% and a volume of 15ml, sealed and placed in an oven for 2 days at 60°C; the catalyst after standing Dry it in an oven at 150°C for 12 hours, then put it in a muffle furnace for calcination at 500°C for 4 hours; wash the calcined catalyst fully with deionized water, and put it in an oven for full drying. Add the dried catalyst to a sodium hydroxide solution with a volume of 15ml of sodium borohydride, wherein the concentration of sodium borohydride is 0.8g / L, and the concentration of sodium hydroxide is 10mg / L; filter after soaking for 3h; Fully washed with deionized water and fully dried in an oven to obtain a regenerated catalyst sample.

Embodiment 2

[0033] In Example 1, the hydrochloric acid was changed to nitric acid with a mass fraction of 10%, the sodium borohydride concentration in the reducing solution was changed to 1.2 g / L, and the sodium hydroxide was changed to a concentration of 15 mg / L sodium bicarbonate.

Embodiment 3

[0035] In Example 1, the sodium borohydride in the reducing solution was changed to potassium borohydride with a concentration of 1.0 g / L, and the sodium hydroxide was changed to potassium hydroxide with a concentration of 12 mg / L.

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Abstract

The invention discloses a CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst reactivating method in coal ethylene glycol production technical synthesizing processes. The method comprises four steps of baking at high temperature CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst of Pd / a-Al2O3 to remove impurities like organic matters and carbon carried by carriers, and converting palladium on the catalyst into palladium oxide; reacting the catalyst with acid to convert the palladium oxide into soluble palladium salt, and together drying and baking the reacted solution and the carriers to redistribute and load palladium products on the carriers; performing reduction treatment to obtain reactivated palladium catalyst of Pd / a-Al2O3. The reactivated catalyst can restore the quality of fresh catalyst. The CO gas-phase oxidative coupling oxalate synthesizing palladium catalyst reactivating method can effectively reactivate deactivated palladium catalyst to obtain the catalyst excellent in active indexes.

Description

technical field [0001] The invention relates to a regeneration method of a deactivated noble metal catalyst, in particular to a regeneration method after deactivation of the catalyst used in the CO gas-phase oxidative coupling synthesis process of dimethyl oxalate in the coal-to-ethylene glycol synthesis process. Background technique [0002] As of January 2016, the total production capacity of major coal-to-ethylene glycol production enterprises in my country is 2.2 million tons per year. In the next few years, multiple sets of ethylene glycol industrial devices with a capacity of more than 100 kt / a will be put into operation one after another. [0003] The coal-to-ethylene glycol technology is divided into three important processes. The first step is to remove the hydrogen from the CO in the coal synthesis gas to below 100ppm under the action of a dehydrogenation catalyst to obtain refined CO, referred to as the dehydrogenation process; the second step is Refined CO is oxi...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B01J38/02B01J38/60B01J38/62B01J38/64B01J23/44B01J23/96C07C67/36C07C69/36
CPCY02P20/584B01J38/02B01J23/44B01J23/96B01J38/60B01J38/62B01J38/64C07C67/36C07C69/36
Inventor 姚元根黄园园潘鹏斌张鑫覃业燕陈健珊郭榕王彦端
Owner FUJIAN INST OF RES ON THE STRUCTURE OF MATTER CHINESE ACAD OF SCI
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