Dakk's Drop-in Liners Provide Fast Fluid Containment Solution
Drop-in liners are said to be a quick, cost-effective solution for leaking steel and concrete tanks that are used for metal finishing.
Dakk’s flexible drop-in liners for fluid containment and corrosion control are used in tanks and sumps for primary or secondary containment, often in the plating and metal finishing industry. The drop-in liners are said to be a quick, cost-effective solution for leaking steel and concrete tanks that are used for metal finishing, including anodizing, hardcoat anodize, chrome plating, electroless nickel, zinc and other metal cleaning and treatment solutions. The liners are manufactured as a one-piece membrane, enabling easy installation.
Dakk Mfg.|405-395-2139|dakkmfg.com
Related Content
-
Top 5 Areas to Consider Automation of Plating Operations
Automation for finishing operations can lead to improvements in process time, repeatability and consistency of quality. Yet, processes that make sense to explore for these operational efficiencies may not always be readily apparent.
-
NASF/AESF Foundation Research Project #122: Electrochemical Approaches to Treatment of PFAS in Plating Wastewater - 7th Quarterly Report
The NASF-AESF Foundation Research Board has selected a project on addressing the problem of PFAS and related chemicals in plating wastewater streams, studying PFAS destruction via electrooxidation and electrocoagulation. Our last report described the results from experiments of EO with a Magnéli phase Ti4O7 anode on the degradation of eight perfluoroalkyl acids (PFAAs). In this seven quarter report, we describe work to further explore how the degradation of different PFAAs are related to their molecular structures.
-
NASF/AESF Foundation Research Project #122: Electrochemical Approaches to Treatment of PFAS in Plating Wastewater - 9th Quarterly Report
The NASF-AESF Foundation Research Board selected a project addressing the problem of PFAS and related chemicals in plating wastewater streams. This report covers the ninth quarter of work (January-March 2023). In this report, we describe our work on evaluating the performance of PFAS degradation by electrooxidation using surface fluorinated Ti4O7 anodes in batch mode.
