Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery
This pilot study investigated an automated pilot plant for removing microplastics (MPs) from industrial wastewater that are generated during packaging production. MP removal is based on organosilane-induced agglomeration-fixation (clump & skim technology) followed by separation. The wastewater h...
| 出版年: | Clean Technologies |
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| 主要な著者: | , , , , , |
| フォーマット: | 論文 |
| 言語: | 英語 |
| 出版事項: |
MDPI AG
2025-08-01
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| 主題: | |
| オンライン・アクセス: | https://www.mdpi.com/2571-8797/7/3/67 |
| _version_ | 1848777040482795520 |
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| author | Anika Korzin Michael Toni Sturm Erika Myers Dennis Schober Pieter Ronsse Katrin Schuhen |
| author_facet | Anika Korzin Michael Toni Sturm Erika Myers Dennis Schober Pieter Ronsse Katrin Schuhen |
| author_sort | Anika Korzin |
| collection | DOAJ |
| container_title | Clean Technologies |
| description | This pilot study investigated an automated pilot plant for removing microplastics (MPs) from industrial wastewater that are generated during packaging production. MP removal is based on organosilane-induced agglomeration-fixation (clump & skim technology) followed by separation. The wastewater had high MP loads (1725 ± 377 mg/L; 673 ± 183 million particles/L) and an average COD of 7570 ± 1339 mg/L. Over 25 continuous test runs, the system achieved consistent performance, removing an average of 97.4% of MPs by mass and 99.1% by particle count, while reducing the COD by 78.8%. Projected over a year, this equates to preventing 1.7 tons of MPs and 6 tons of COD from entering the sewage system. Turbidity and photometric TSS measurements proved useful for process control. The approach supports water reuse—with water savings up to 80%—and allows recovery of agglomerates for recycling and reuse. Targeting pollutant removal upstream at the source provides multiple financial and environmental benefits, including lower overall energy demands, higher removal efficiencies, and process water reuse. This provides financial and environmental incentives for industries to implement sustainable solutions for pollutants and microplastic removal. |
| format | Article |
| id | doaj-art-e81f3a533bb042ba892cabec9385b156 |
| institution | Directory of Open Access Journals |
| issn | 2571-8797 |
| language | English |
| publishDate | 2025-08-01 |
| publisher | MDPI AG |
| record_format | Article |
| spelling | doaj-art-e81f3a533bb042ba892cabec9385b1562025-09-26T14:30:53ZengMDPI AGClean Technologies2571-87972025-08-01736710.3390/cleantechnol7030067Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste RecoveryAnika Korzin0Michael Toni Sturm1Erika Myers2Dennis Schober3Pieter Ronsse4Katrin Schuhen5Wasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyWasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyWasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyWasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyWasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyWasser 3.0 gGmbH, Neufeldstr. 17a–19a, 76187 Karlsruhe, GermanyThis pilot study investigated an automated pilot plant for removing microplastics (MPs) from industrial wastewater that are generated during packaging production. MP removal is based on organosilane-induced agglomeration-fixation (clump & skim technology) followed by separation. The wastewater had high MP loads (1725 ± 377 mg/L; 673 ± 183 million particles/L) and an average COD of 7570 ± 1339 mg/L. Over 25 continuous test runs, the system achieved consistent performance, removing an average of 97.4% of MPs by mass and 99.1% by particle count, while reducing the COD by 78.8%. Projected over a year, this equates to preventing 1.7 tons of MPs and 6 tons of COD from entering the sewage system. Turbidity and photometric TSS measurements proved useful for process control. The approach supports water reuse—with water savings up to 80%—and allows recovery of agglomerates for recycling and reuse. Targeting pollutant removal upstream at the source provides multiple financial and environmental benefits, including lower overall energy demands, higher removal efficiencies, and process water reuse. This provides financial and environmental incentives for industries to implement sustainable solutions for pollutants and microplastic removal.https://www.mdpi.com/2571-8797/7/3/67microplasticsmicroplastic removalsol–gel processwastewater treatmentchemical oxygen demandrecycling |
| spellingShingle | Anika Korzin Michael Toni Sturm Erika Myers Dennis Schober Pieter Ronsse Katrin Schuhen Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery microplastics microplastic removal sol–gel process wastewater treatment chemical oxygen demand recycling |
| title | Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery |
| title_full | Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery |
| title_fullStr | Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery |
| title_full_unstemmed | Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery |
| title_short | Upstream Microplastic Removal in Industrial Wastewater: A Pilot Study on Agglomeration-Fixation-Reaction Based Treatment for Water Reuse and Waste Recovery |
| title_sort | upstream microplastic removal in industrial wastewater a pilot study on agglomeration fixation reaction based treatment for water reuse and waste recovery |
| topic | microplastics microplastic removal sol–gel process wastewater treatment chemical oxygen demand recycling |
| url | https://www.mdpi.com/2571-8797/7/3/67 |
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