The new generation of well-established finely dispersed Lewatit ion exchange resins from LANXESS has proven its worth in practice: Lewatit MDS resins significantly increase the efficiency of brine treatment in chlor-alkali electrolysis using the membrane method. They make an effective contribution to preventing damage to the latest generation of ion exchange membranes used for electrolysis, which are becoming more and more sensitive, thus prolonging their service life and reducing the energy costs of the process. Dr. Jenny Barbier, Technical Marketing Manager in the LANXESS Liquid Purification Technologies business unit, will present the new class of ion exchange resins applied to protect these membranes at the Flemion Seminar, which will be held in Amsterdam from October 23 to 25, 2018. At the conference, which will be attended by representatives of the global chlor-alkali industry, Barbier will explain the properties of the products and present new case studies in her presentation “New Advances in Brine Purification by Novel Chelating Resins.” 

 

In the electrochemical process of chlor-alkali electrolysis, sodium hydroxide, chlorine gas, and hydrogen are produced from a highly concentrated saline solution (brine) – these are important basic chemicals for the production of PVC, paper, cellulose, disinfectants, and bleach, for example. The membrane method was developed for this purpose in the 1970s. It can be run efficiently and safely, offers energy savings of around 25 percent compared to other processes and does not require mercury or asbestos. Due to these and other advantages, it has been used for more than two decades for all new plants and older plants are increasingly being converted to the membrane method. Since impurities can irreversibly damage the cost-intensive fluorinated ion exchange membranes used in electrolysis, the brine is finely purified using ion exchangers. 

 

With the particularly fine monodisperse, macroporous chelating resins of the Lewatit MDS series, brine purification in chlor-alkali electrolysis using the membrane method can be made much more efficient. The decisive difference between the new resin types and those previously offered is the bead diameter. This is only 390 µm for the MDS types (Mono Disperse Small, such as Lewatit MDS TP 208) and is thus around 40 percent smaller than for the Lewatit MonoPlus TP 208, which is also monodisperse. As a result of this difference, the MDS types are characterized by improved kinetics, a higher degree of regeneration and a significantly increased total and operating capacity especially for alkaline earth cations. They have optimal mechanical and osmotic stability. 

 

Barium and strontium ions are separated particularly efficiently from the brine. “Because of the low selectivity of many other resins and the slow exchange kinetics, this is particularly remarkable – and is increasingly the focus of customers,” says Barbier. The chelating resin also binds the lighter elements of the alkaline earth group, i.e. calcium and magnesium. “The improved removal rates are an important advantage because the reduced leakage helps to increase the service life of the electrolysis membranes. In this respect, the MDS resins have already anticipated the continuously progressing membrane development by allowing the user to protect their membranes better through significantly lower concentration tolerances for alkaline earth ions,” explains Barbier.

 

The Lewatit MDS chelating resins open up a whole series of economic advantages for the electrolysis operator, particularly in terms of significant savings in energy costs, and are primarily based on the following effects:

 

The new resin types are already being used successfully on an industrial scale. In her presentation at the Flemion Seminar, Barbier explaines the benefits for the industry using two case studies. One from a leading European PVC supplier from Germany and one from a chemical manufacturer from South India that ensures a supply of basic and specialty chemicals.