Khan, M.M. and Asghar, H.M.A. and Saulat, H. and Chawla, M. and Rafiq, S. and Khan, M.M. and Ya Jie, W. and Aslam, M. and Mukhtar, A. (2021) Hazardous wastewater treatment by low-cost sorbent with in situ regeneration using hybrid solar energy-electrochemical system. Water Environment Research, 93 (9). pp. 1554-1561. ISSN 10614303
Full text not available from this repository.Abstract
Hazardous industrial wastes negatively impact the environment by creating issues for aquatic as well as human's life. This study investigates the treatment of hazardous industrial wastewater using cost-effective graphite adsorbent along with electrochemical regeneration integrated with renewable solar energy. The synthetic industrial effluent containing crystal violet dye was treated using an adsorbent (Nyex� 1000) having a surface area of 1.0 m2 g�1. The efficiency of removing solute was found to be more than 90. The adsorbent regeneration efficiency was achieved at 99.5 by passing a charge of 100 C g�1 at current density of 10 mA cm�2 for 1 h. Solar energy was integrated with electrochemical reactor for the regeneration of adsorbent to make the system cost-effective and self-sustainable. Practitioner points: Industrial hazardous wastewater treatment with a cost-effective graphite integrated adsorbent. Development of renewable solar energy-integrated with electrochemical system for regeneration. Regeneration efficiency of adsorbent Nyex� 1000 was achieved around 99.5 with integrated system. Sustainable system was introduced to incorporate with renewable energy for waste water treatment. © 2021 Water Environment Federation
Item Type: | Article |
---|---|
Additional Information: | cited By 5 |
Uncontrolled Keywords: | Cost effectiveness; Costs; Effluents; Graphite; Hazards; Industrial wastes; Industrial water treatment; Sewage; Waste treatment; Wastewater treatment, Adsorbent regeneration; Electrochemical reactor; Electrochemical regeneration; Electrochemical systems; Hazardous industrial wastes; Hazardous wastewaters; Industrial wastewaters; Regeneration efficiency, Solar energy, carbimazole; crystal violet; graphite; industrial effluent; sorbent; graphite, alternative energy; effluent; graphite; industrial waste; regeneration; surface area; wastewater; wastewater treatment, Article; controlled study; human; waste water management; solar energy; wastewater; water management, Graphite; Humans; Solar Energy; Waste Water; Water Purification |
Depositing User: | Mr Ahmad Suhairi UTP |
Date Deposited: | 10 Nov 2023 03:29 |
Last Modified: | 10 Nov 2023 03:29 |
URI: | https://khub.utp.edu.my/scholars/id/eprint/14552 |