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EDI Introduction

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The advanced EDI technology is typically implemented downstream Reverse Osmosis (RO) equipment and mainly used for the production of High Purity and Ultra Pure Water. The environmental friendly operating combined RO-EDI systems, as successor for the more traditional Ion Exchange resin installations, are nowadays the standard for the production of demineralized water. EDI equipment can operate continuous and produces a constant quality pure water. The systems have a very limited footprint and frequent maintenance is not applicable. Electricity is all that’s needed for the electrochemical process operation.
Companies constantly focus on the reduction of operating costs, improve efficiency and eliminate the use of hazardous chemicals in the workplace. Such goals embraced the increasing implementation of the EDI technology to produce high purity- and ultrapure water.
Even though in some sectors EDI is still considered as a new technology, in reality many thousands of systems are successful operating since 25 years in different environments. In these periphrasis the EDI history, the basic principles and features are further explained.

EDI History

EDI is first described in a scientific publication at 1955 as a method to remove trace radioactive materials from water (Walters, et al.) and until the first commercial system in early 1987 many studies and patents has been developed. Since 1987 until today a number of commercial EDI manufacturers entered the market. Due to the rapidly emerging needs of tomorrow and the implementation of Corporate Social Responsibility, foster the interest in EDI technology

EDI Applications

Electro deionization is the technology of choice for projects that require pure product water and stringent wastewater discharge requirements.
Among several applications is the production of demineralized process water for the power and petrochemical industry including (high pressure) boiler feed water and pure water injection in gas turbines. Other typical EDI pure water processes are for the semi-conductor industry and optical-glass manufacturing.
Since decades the EDI technology is the standard technology as final step for the production of Purified Water according the guidelines of the United States (USP) and European Pharmacopoeia (EP). During operation, EDI modules are at least considered bacteriostatic and additionally these can be frequently hot water sanitized.

Typical applications of EDI are:

- Demineralized feed water for (supercritical high pressure) boilers including Concentrated Solar Plants
- Pure water injection in turbines for NOx reduction
- Microelectronics / Semiconductor rinse water
- Purified and Highly Purified Water for the pharmaceutical industry
- Demineralized water for the (petro)chemical industry
- Hospital applications including Hemodialysis
- University and laboratory

 

How EDI is built and operates

Electro deionization (EDI) is a process that removes ions such as salts, acids and bases. Weakly ionized materials like dissolved silica, carbon dioxide, boron and some organics are removed as well. The bulk of the ions is removed in the upper part of the module (working bed) and transported via the conductive surface of the ion exchange (IX) resin beads towards the IX membranes. The applied DC current is the driving force for the ion transport to and migration through the IX membranes into the concentrate compartments.

In the lower part of the module, the so called “polishing bed”, the remaining ions and especially the weakly charged ions are removed by the “ion exchange” phenomena. The ion exchange process is driven by a continuous water splitting (electrical regeneration).

To further explain the process in detail let’s build a basic EDI module. First a container is filled with water containing salts and additionally on the two ends two electrodes connected to a DC power supply are introduced.

Under influence of the applied electrical potential (DC Voltage) the positive anions and the negative cations move towards the anode and cathode respectively. To be able to separate the +anions and –cations, a number of ion selective IX membranes are introduced in the container as well, creating alternately “product” and “concentrate” compartments. As a result of the transport of anions in one direction and of cations in the opposite direction, ions can pass one membrane and are then repelled by the next membrane. In this way all ions are trapped in the concentrate compartments. In an EDI module a part of the feed flow, approximately 5% of the volume, is used to continuous wash out the ions from the concentrate compartments. This concentrate outlet, also called reject stream, is recirculated upstream the RO system to be recovered.

As most of the ions are already removed in the upper part of the product compartments, the electrical resistance between membranes and resin beads increases significantly in the lower part. As a result also the local voltage potential increases and at a certain voltage difference, water splitting occurs. Water (H2O) splits into hydrogen (H+) and hydroxide (OH-) ions. The H+ and OH- ions replaces trace anions of elements like sodium and chloride and weakly charged ions like silica, boron and CO2 on the resin beads so these are able to escape into the concentrate compartments. More than 80% of the power is used for water splitting and possible excess of H+ and OH- ions also move into the concentrate compartments and others form H2O again.

This basic repeating element of the EDI, called a "cell-pair", is illustrated in Figure 1. The "stack" of cell-pairs is positioned between the two electrodes. Under the influence of the applied DC voltage potential, ions are transported across the membranes from the product compartments into the concentrate compartments. Thus, as water moves through the product compartments, these become free of ions. This stream is the pure water product stream.


CEM: Cation exchange membrane. AEM: Anion exchange membrane

In the concentrate stream, electrical neutrality is maintained. Transported ions from the two directions neutralize one another's charge.

In an EDI device, the compartments are filled with electrically active media such as ion exchange resin. The IX resin enhances the transport of ions and can also participate as a substrate for electrochemical reactions, such as splitting of water into hydrogen (H+) and hydroxyl (OH-) ions. Different media configurations are possible, and used by different manufacturers, such as intimately mixed anion and cation exchange resins (mixed bed or MB) or separate sections of ion-exchange resin, each section substantially comprised of resins of the same polarity: e.g., either anion or cation resin (layered bed or LB and single bed or SB).
The electrically water dissociation produce the continuous regeneration of resins by hydrogen and hydroxide ions. This dissociation preferentially occurs at bipolar interfaces in the ion-depleting compartment where localized conditions of low solute concentrations are most likely to occur (Simons). Regenerating the resins to their H+ and OH- forms allows EDI devices to remove weakly ionized compounds such as carbonic and silicic acids and to remove weakly ionized organic compounds.

Beneficial EDI characteristics

The electro deionization technology distinguish itself as a continuous ion exchange technique for the production of (ultra) pure water without the need for chemical regeneration and waste neutralization steps. During the process the polishing part of the resin is continuous regenerated. In comparison with the more traditional ion exchange systems this reduces facility costs such as waste neutralization equipment and hazardous fumes ventilation. Obvious the lack of chemical usage, handling and storage helps to improve health and safety, as well as corrosion prevention in facilities and equipment.
EDI modules can be fed with feed water conductivity equivalent up to 100 µS/cm and water hardness up to 4 ppm, allowing a wider range of applications. Electro deionization systems can achieve up to 99,9 percent salt removal, reduce the levels of individual ionic species to parts-per-billion or even parts-per-trillion levels, and produce high-purity water with a resistivity of 10 to 18 MegOhm.cm (0,1 to 0,055 microS/cm conductivity).
Since the EDI concentrate (or reject) stream contains the feed water contaminants at 5-20 times higher concentration, it can usually be recycled back to the RO pretreatment. The recycle option increases the total plant recovery and so minimizing the valuable total water consumption.

Summary of EDI features:

- Environmental friendly, no regeneration chemicals are needed
- EDI is a continuous process and produces a constant quality
- EDI systems are extremely compact and require minimum footprint
- Low operating cost, electricity only
- Very fair capital cost
- Minimum facility requirements and operator attention
- High system recovery
- 1000's of systems installed worldwide up to a capacity of 1.500 m3/h

References

For more detailed information please have a look at ourreference projects.

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Salt movement

 

pure water product stream

Figure 1. Stack of cell pairs.