Preparation method and applications of iron-carbon micro-electrolysis material for maintaining long-term catalytic activity of Fenton system

A micro-electrolysis and graphitized carbon technology, applied in the field of highly toxic pollutant treatment, can solve the problems of shortening the service life of iron-carbon fillers, aggravating iron corrosion and loss, and increasing the operating cost of enterprises, achieving high load capacity and high utilization rate. , the effect of increasing the timeliness

Active Publication Date: 2019-09-20
RES CENT FOR ECO ENVIRONMENTAL SCI THE CHINESE ACAD OF SCI
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  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

However, since the optimal pH of micro-electrolysis operation is less than 4, in a more acidic solution, the iron exposed on the edge of the filler is easily oxidized by the dissolved oxygen in the water, aggravating the corrosion and loss of iron, and increasing the iron ion content in the water sample
Although these iron ions can be used as co-coagulants to remove organic pollutants through flocculation and precipitation, the particles in these sediments and wastewater will adhere to the surface of fillers (especially zero-valent iron) to form a passivation film that blocks the interaction between fillers and wastewater. Effective contact, resulting in a decrease in the activity of the filler, greatly shortening the service life of the iron-carbon filler
Therefore, most of the commercialized iron-carbon fillers need to be replaced or regenerated after half a year to one year of use, which increases the operating cost of the enterprise.

Method used

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  • Preparation method and applications of iron-carbon micro-electrolysis material for maintaining long-term catalytic activity of Fenton system
  • Preparation method and applications of iron-carbon micro-electrolysis material for maintaining long-term catalytic activity of Fenton system
  • Preparation method and applications of iron-carbon micro-electrolysis material for maintaining long-term catalytic activity of Fenton system

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0045] Example 1 : The preparation method of highly dispersed core-shell type Fe-C micro-electrolytic material of the present invention

[0046] The synthesizing schematic diagram of highly dispersed core-shell type Fe-C micro-electrolytic material provided by the present invention is as follows figure 1 Shown, its specific preparation method is:

[0047] First, weigh a certain amount of FeCl 3 Add terephthalic acid and terephthalic acid into a zirconia grinding tank, then add a certain volume of tetramethylammonium hydroxide solution and 3-4 zirconia grinding balls, and grind for 0.5-2h at a speed of 300 rpm to obtain Fe-MOFs material: The prepared Fe-MOFs and montmorillonite are fully mixed, and heated at a high temperature of 800°C for 2 hours under the protection of nitrogen to obtain a highly dispersed core-shell Fe-C micro-electrolytic material.

Embodiment 2

[0048] Example 2 : Structural characterization of highly dispersed core-shell Fe-C microelectrolytic materials of the present invention

[0049]This embodiment is the structural characterization of the highly dispersed core-shell Fe-C micro-electrolytic material, specifically as follows:

[0050] 1.TEM

[0051] The particle size and morphology of highly dispersed core-shell Fe-C microelectrolytic materials were analyzed by transmission electron microscope H7500 (Hitachi, Japan).

[0052] from figure 2 It can be seen that the diameter of the zero-valent iron inner core of Fe-C nanoparticles is 15-30 nm, and the thickness of the carbon shell is about 5 nm. The core-shell Fe-C is embedded in a large amount of graphitized carbon, which increases the stability of the zero-valent iron in the core. The core-shell Fe-C nanoparticles are uniformly dispersed between the lamellar structures and the inner and outer surfaces of the montmorillonite with a layered structure.

[0053] ...

Embodiment 3

[0062] Example 3 : Catalytic performance test of highly dispersed core-shell type Fe-C micro-electrolytic material of the present invention

[0063] In this example, phenol and methyl orange were selected as representatives, and the catalytic performance of the highly dispersed core-shell Fe-C micro-electrolytic material was tested.

[0064] The operation steps of the test are as follows: configure 100 mg / L of phenol and 50 mg / L of methyl orange standard 50 mL, place it in a 100 mL polyethylene plastic vial, add 25 mg of highly dispersed core-shell Fe-C micro-electrolytic material, and make the catalyst The concentration is 0.5g / L, then add a certain concentration of H 2 o 2 . Shake in a shaker, take 0.5mL samples every once in a while, add 0.5mL ethanol, take the supernatant after centrifugation, and test phenol, methyl orange, TOC and Fe respectively. 2+ and H 2 o 2 determination. Phenol was measured by HPLC-UV, TOC was detected by TOC / TN analyzer, methyl orange, Fe ...

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Abstract

The invention provides a preparation method and applications of an iron-carbon micro-electrolysis material for maintaining the long-term catalytic activity of a Fenton system. According to the present invention, the catalyst is derived from an iron metal organic framework (Fe-MOFs) and montmorillonite; after Fe-MOFs prepared by a mechanochemical method are mixed with montmorillonite, high temperature carbonizing is performed to form a core-shell type iron-carbon filler micro-electrolysis material (Fe@C-MMT) dispersed between the montmorillonite sheet structures; the inefficient decomposition of hydrogen peroxide can be delayed by highly dispersing the Fe@C-MMT material in the water sample, and the hydroxyl radicals are selectively generated, such that the hydrogen peroxide in the system has long-term oxidation ability; the catalyst has a certain pH value adjustment ability, wherein organic pollutants can be efficiently degraded when the initial pH value is 3-6.5; and the catalyst has good stability, can be reused multiple times, and is suitable for removing refractory organic pollutants such as phenol, methyl orange and the like in environmental water samples by advanced oxidation technology Fenton reactions.

Description

technical field [0001] The invention belongs to the technical field of highly toxic pollutant treatment, and relates to the preparation of a highly dispersed core-shell type iron-carbon micro-electrolysis nanomaterial that maintains the long-term catalytic activity of a Fenton system and its application as a heterogeneous Fenton catalyst to degrade pollutants. Background technique [0002] China is in a period of rapid economic growth. The rapid development of industry is the guarantee of rapid economic growth, but at the same time, a large amount of waste water is discharged in industrial production. Industrial wastewater has the characteristics of many types of pollutants, complex components, high COD concentration, poor biodegradability, and high toxicity. If it is not effectively and comprehensively controlled, it will cause serious environmental pollution and ecological damage, endanger people's health, and hinder the further sustainable development of the economy. The...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B01J23/745B82Y30/00B82Y40/00C02F1/72C02F101/30C02F101/34C02F101/38
CPCB01J23/745B82Y30/00B82Y40/00C02F1/722C02F1/725C02F2101/308C02F2101/345C02F2305/026
Inventor 蔡亚岐牛红云何东伟
Owner RES CENT FOR ECO ENVIRONMENTAL SCI THE CHINESE ACAD OF SCI
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