Ferrics, alums, and polymers are commonly used to treat water and wastewater. There are several reasons why these substances require specialized storage:
By providing the right kind of storage for these chemicals, safety can be maintained and the integrity of the product can be preserved.
A flocculant is a substance that promotes the clumping of particles so that they may be removed from water. Flocculants are essential in proper water treatment. One particularly popular flocculant is Ferric Chloride.
Ferric Chloride has been commercially available in the United States since the 1930's, but it is only in the last 20 years that we've seen a trend of increased acceptance of Ferric Chloride for drinking water treatment. This trend is likely due to the chemical's improvements in product economics, quality and availability in the United States.
As one of the purest and most concentrated forms of iron commercially available for water treatment, Ferric Chloride has a unique distinction. In order to produce Ferric Chloride, Ferrous Chloride must be used. Oxidation of Ferrous Chloride with Chlorine creates this new compound.
Ferric Chloride offers versatility in the water treatment industry, serving as a flocculant and coagulant, as well as a reactant. It promotes faster sedimentation in general and, specifically, better sedimentation in cold water, making it an ideal choice for the industry.
Ferric Chloride has several applications in the potable water industry, including both high and low turbidity removal, enhanced coagulation, NOM (natural organic matter), DBP (disinfection by-products) precursor removal, color removal, arsenic reduction, softening solids sedimentation aid, and as a filtration aid.
It is extremely important that we handle Ferric Chloride and all chemicals with respect and in a safe manner. This holds true to safe chemical storage as well.
Ferric Chloride is also used as an etching medium, meaning it should not be stored in a FRP tank, as the chemical would compromise the tank. For safe storage, we recommend a high-density crosslinked polyethylene tank.
Not all high-density polyethylene tanks are created equal. Although they sound nearly identical, linear polyethylene and crosslinked polyethylene (XLPE) chemical storage tanks have significant differences. Those differences could impact your organization’s bottom line, your people’s safety and the operations of your facility.
Both linear polyethylene and XLPE tanks are made from heated resins to form cured plastic. However, the differences in their production create very different polyethylenes with very different structural strength.
Crosslinking is simply the formation of bonds between the polymer chains. These bonds, equal in strength and stability to the principal bonds along the polymer backbone, tie the polymers together, thus dramatically increasing molecular weight. In fact, the length of the polymer chains and, therefore, the physical properties, are much better than can ever be achieved without crosslinking.
The result is a plastic that possesses impact resistance, tensile strength and resistance to fracture that linear polyethylene just can’t match. These qualities make crosslinked polyethylene an excellent choice when tank integrity is critical. The structural integrity, heat resistance and useful life in most cases are unparalleled.
Poly Processing has NSF-61 certification for 38 chemicals on its crosslinked polyethylene tanks.
Ferric chloride is also a high fuming chemical. These fumes can potentially defoliate surrounding trees and plants.
When storing Ferric Chloride in a chemical storage tank, a fume-tight manway lid cover prevents fumes from escaping the tank. Adding a scrubber provides a cost-effective solution to address any potential fuming into the atmosphere while using ferric chloride.
Our crosslinked polyethylene tanks are able to store up to 96% concentration of Ferric Chloride, with a tank that has a specific gravity rating of 1.65, with PVC fitting materials, EDPM gaskets, and titanium bolts.
Learn more about Ferric Chloride by downloading our complete product catalog today, or contact a chemical storage tank expert to get answers to your questions.
Ferric chloride is widely used in water and wastewater treatment because of its effectiveness as a coagulant. While it is a familiar chemical in many plants, its corrosive nature means storage details matter more than many operators expect.
The following considerations build on the existing guidance and address common issues seen in long-term ferric chloride storage applications.
Ferric chloride is commonly delivered and stored in concentrations between 30 percent and 42 percent by weight. As concentration increases, so does specific gravity.
Tank selection should account for:
Using an underspecified tank can lead to excessive wall stress and reduced service life, even when the material itself is chemically compatible.
Ferric chloride behaves differently than alum and many polymer coagulants.
Compared to alum, ferric chloride:
Facilities converting from alum to ferric chloride often overlook these differences, which can lead to premature failures if storage systems are not reevaluated.
In ferric chloride systems, fittings are often the first components to fail.
Best practices include:
All connections should be inspected periodically, especially during the first year of operation, when settling and thermal movement are most likely to occur.
Ferric chloride is regulated as a corrosive substance, and many jurisdictions require secondary containment to reduce environmental risk.
Secondary containment may be achieved through:
Containment requirements vary by location, so facilities should confirm expectations with local environmental authorities before installation.
Ferric chloride is typically stored at ambient temperatures, but environmental conditions still influence system performance.
Higher temperatures can:
Tanks should be installed away from direct heat sources and designed to maintain acceptable process temperatures during normal operation.
Routine inspection plays a key role in long-term ferric chloride storage reliability.
Recommended practices include:
Annual inspections should follow the manufacturer’s installation and operation guidance to ensure continued safe operation.
Ferric chloride is effective, economical, and widely used. It is also unforgiving when storage systems are not properly designed.
Matching tank material, design, fittings, and containment to the specific application helps reduce maintenance costs and unplanned downtime over the life of the system. Working with an experienced manufacturer such as Poly Processing helps ensure ferric chloride storage systems are specified correctly from the start.