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♦以具有內過氧橋鍵的無機材料為氣液界面介導材料,通過系統設計,FR-ONE獨特介導,水體媒介,激惹產生多種、多量高活性無機自由基簇,主要包括SO4·−、 CO3·− 、 (·OH)、(·Cl)、(HO2·)等高活性粒子簇,其電極電勢可根據實際應用需要,強化到達2.5--3.5v作為液體門控技術結構與功能性材料液體門;將表面潤濕性可調的有機高分子彈性多孔膜材料、石墨相氮化碳、富含氧空位復合材料等充當固體骨架門框。
♦塔式旋流交換,微尺度孔道利用毛細力作用,將功能性液體穩定地填充在孔道內部,在水與空氣界面物質傳輸的一定壓力下迅速開啟,在多孔材料孔道內壁形成有液體層的通路,并具有可逆調控性,鏈式礦化,實現了對低濃度VOC及惡臭異味污染物處理量的數量級提升。與RTO\RCO冷凝等工藝組合,可實現對工業廢氣、高濃度VOC的有效治理。
♦利用IRC液體門控專有技術,通過管路連接、自動化、微流控技術、程序化控制等集成應用,進一步實現免維護、安全高效、低成本系統運行。
Technical Principle
♦ Using inorganic materials containing endoperoxide bridges as gas-liquid interface mediators, the FR-ONE system uniquely facilitates the generation of diverse, highly reactive inorganic free radical clusters (including SO?·?, CO?·?, ·OH, ·Cl, HO?·, etc.) through aqueous activation. The electrode potential can be enhanced to 2.5–3.5 V as required for practical applications, serving as both structural and functional liquid "gates" in the liquid gating technology. Organic polymer elastic porous membranes with tunable surface wettability, graphitic carbon nitride, and oxygen vacancy-rich composite materials act as solid framework "doorframes."
♦ Through tower-type vortex exchange and microchannel capillary forces, functional liquids are stably filled within the channels. These rapidly open under specific pressure conditions at the water-air interface, forming liquid-lined pathways within the porous material channels with reversible controllability. Chain mineralization enables an order-of-magnitude improvement in treating low-concentration VOCs and odorous pollutants. Combined with processes such as RTO/RCO and condensation, it achieves effective treatment of industrial waste gases and high-concentration VOCs.
♦ Utilizing proprietary IRC liquid gating technology integrated with piping, automation, microfluidics, and programmed control, the system achieves maintenance-free, safe, efficient, and low-cost operation.
反應原理
高能SRR無機自由基簇:
Reaction Mechanism
High-Energy SRR Inorganic Free Radical Clusters:
Activation of the radical source with water generates diverse and abundant inorganic free radical clusters (collectively referred to as the SRR Free Radical System), primarily including oxygenated acid radicals (sulfate radicals (SO?·?), carbonate radicals (CO?·?), phosphate radicals (H?PO?·, HPO?·, PO?·²?)), hydroxyl radicals (·OH), chlorine radicals (·Cl), hydroperoxyl radicals (HO?·), superoxide anion radicals (O?·?), and singlet oxygen (¹O?). With a standard oxidation potential of E? = 2.5–3.1 eV, this high-energy potential enables the mineralization of nearly all industrial waste gases, volatile organic compounds (VOCs), and odorous substances.
Principle of Chain Reaction between SRR Free Radical Clusters and Organic Pollutants (VOCs)
(Illustrated using the sulfate radical (SO?·?) as an example)
The SRR free radical clusters initiate efficient chain reactions with organic pollutants through three primary mechanisms:
1. Hydrogen Atom Abstraction (HAA)
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Primary Targets: Saturated organic compounds including alcohols, alkanes, ethers, and esters
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Reaction Mechanism:
SO?·? + R-H → HSO?? + R·
The sulfate radical abstracts a hydrogen atom from the organic substrate, generating a carbon-centered radical (R·) that subsequently undergoes further oxidation.
2. Addition Reaction
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Primary Targets: Unsaturated compounds containing C=C bonds, particularly alkenes
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Reaction Mechanism:
SO?·? + H?C=CH-R → ·O?S-CH?-CH·-R
The radical adds across the electron-rich double bond, forming a carbon-centered radical adduct that rapidly undergoes subsequent degradation.
3. Electron Transfer Reaction
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Primary Targets: Aromatic compounds and other electron-rich molecules
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Reaction Mechanism:
SO?·? + Ar-H → SO?²? + Ar-H·?
Single-electron transfer generates radical cations that initiate ring-opening and mineralization pathways.
Chain Propagation Characteristics:
The carbon-centered radicals (R·) generated through these mechanisms react rapidly with dissolved oxygen or other radical species, propagating a continuous chain reaction that ultimately mineralizes VOCs to CO?, H?O, and inorganic salts. This multi-pathway mechanism ensures effective degradation of diverse VOC structures across varying concentration ranges.
橡膠、制藥、印染、涂裝、食品、石油、石化、污水處理等廠礦企業VOC廢氣、異味氣體治理。
Application Areas
This technology is deployed for VOC and odorous gas treatment across multiple industrial sectors, including:
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Rubber
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Pharmaceuticals
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Textile Dyeing
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Coating & Painting
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Food Processing
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Petroleum
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Petrochemicals
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Wastewater Treatment Plants
It effectively addresses waste gas and odor control challenges in factories and mining enterprises within these industries.
