Chlor-alkali Process with Subsequent Polyvinyl Chloride Production─Cost Analysis and Economic Evaluation of Demand Response

Klaucke, Franziska; Muller, Robert U.; Hofmann, Mathias; Weigert, Joris; Fischer, P.; Vomberg, Sebastian; Tsatsaronis, George; Repke, Jens‐Uwe

doi:10.1021/acs.iecr.2c04188

Ind. Eng. Chem. Res.

2023

DOI: 10.1021/acs.iecr.2c04188

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Chlor-alkali Process with Subsequent Polyvinyl Chloride Production─Cost Analysis and Economic Evaluation of Demand Response

Franziska Klaucke

Robert U. Muller

Mathias Hofmann

et al.

Abstract: Demand response is a viable option to cope with the increasing demand for flexibility of an energy system based on renewables. Several studies have shown that the electricity-intensive chlor-alkali process has high potential. Previous research primarily focused on process engineering to determine technological flexibility potentials or optimal production scheduling. However, these potentials can only be realized if they are economically viable. This requires knowledge of the costs of a demand response, includi… Show more

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Cited by 4 publications

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Decarbonizing integrated chlor-alkali and vinyl chloride monomer production: Reducing the cost with industrial flexibility

Foslie,

Straus,

Knudsen

et al. 2023

Advances in Applied Energy

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Decarbonizing integrated chlor-alkali and vinyl chloride monomer production: Reducing the cost with industrial flexibility

Foslie,

Straus,

Knudsen

et al. 2023

Advances in Applied Energy

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Harnessing Iron Nitride Matrices through Incorporated Cu-Based Moieties for Chlorine Evolution Reaction

Badreldin,

Youssef,

El-Ghenymy

et al. 2024

ACS Appl. Energy Mater.

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Chlorine evolution reaction (CER) is a critical reaction in many processes, such as chlor-alkali electrolysis and electrochemical wastewater treatment. The scarce and high-cost iridium and ruthenium content of benchmark dimensionally stable anodes (DSA) coupled with subpar activities at commercially relevant current densities (≥150 mA cm −2 ) opens the door for additional material groups to be investigated. Herein, a highly porous, conductive, and chemically resilient trigonal ε-Fe 3 N-based electroactive catalytic substrate is used toward CER in industrial acidic brine (4.0 M NaCl, pH = 2) environments. Consecutive hydrothermal-nitridation steps were fine-tuned for homogeneous dispersion of Cu 3 N moieties atop FeN, which exhibited a similar overpotential to DSA at a commercially relevant current density. An approximately 562 mV overpotential was needed to sustain a current density of 200 mA cm −2 for 75 h of chronoamperometric conditions. Moreover, online GC measurements with a chlorine trap were employed to indirectly obtain CER's Faradaic efficiency (FE) by measuring the FE of the competing oxygen evolution reaction. Textural, chemical, and electrochemical characterization techniques were employed to confirm the identity of the developed anodes and depict the electrocatalytic performance. The findings reported herein could offer potential avenues for similar catalytic systems in both conventional CER and emerging electrosynthesis approaches utilizing saline waters.

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Faster decarbonization of heavy industries in low-carbon power grids: using process flexibility for handling grid congestions

Foslie,

Knudsen,

Bjarghov

et al. 2024

Energy Environ. Sci.

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Chlor-alkali Process with Subsequent Polyvinyl Chloride Production─Cost Analysis and Economic Evaluation of Demand Response

Cited by 4 publications

References 70 publications

Decarbonizing integrated chlor-alkali and vinyl chloride monomer production: Reducing the cost with industrial flexibility

Decarbonizing integrated chlor-alkali and vinyl chloride monomer production: Reducing the cost with industrial flexibility

Harnessing Iron Nitride Matrices through Incorporated Cu-Based Moieties for Chlorine Evolution Reaction

Faster decarbonization of heavy industries in low-carbon power grids: using process flexibility for handling grid congestions

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