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Everything You Need To Know To Find The Best Corrosion and Scale Inhibitor

Jun. 09, 2025

Corrosion and Scale Inhibitors - Types, Advantages, Applications

What are Corrosion and Scale Inhibitors?

Corrosion and scale inhibitors are tailored chemicals that delay or prevent corrosion and/or scale formation when added in small concentrations in water that would normally create scale deposits. A day-to-day example is prevention of limescale in washing machines. Corrosion is the deterioration and loss of a material and its critical properties due to chemical, electrochemical and other reactions of the exposed material surface with the surrounding environment. In , Professor Langelier’s research best described water corrosion or scale deposition tendency. He gave conditions in which water is balanced with calcium carbonate, making it possible to predict the likelihood of a given water to either precipitate or dissolve calcium carbonate. Scale inhibitors or antiscalants are generally organic compounds containing sulphonate, phosphate, or carboxylic acid functional groups and chelating agents such as carbon, alum and zeolites that sequester and neutralize a particular ion that may be formed.

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So how can scale inhibition be achieved? – Either by adding substances that react with the potential scale-forming substances so that thermodynamically, a stable region is reached or by adding substances that suppress crystal growth. Low dosages of chemicals are used to prevent scale for extended periods for either surface or equipment treatments. Scale inhibitors are most often used as prevention techniques to reduce the scaling risks in near-wellbore locations and wellbore. In this article we seek to answer the following questions:

What are the different types of corrosion and scale inhibitors?
What are some of the theories behind the mechanism of action?
Is there a selection criteria of corrosion and scale inhibitors?
What are the advantages of corrosion and scale inhibitors?
Are there limitations of corrosion and scale inhibitors?
Where are some of the applications of corrosion and scale inhibitors?

What are the different types of corrosion inhibitors?

A corrosion inhibitor is a chemical compound that, when added to a liquid or gas, decreases the corrosion rate of a material, typically a metal or an alloy, that meets the fluid. The chemicals react with the metal surface or the environmental gases causing erosion, thereby, interrupting the chemical reaction that causes corrosion. The effectiveness of a corrosion inhibitor depends on fluid composition, quantity of water, and flow regime. Inhibitors can work by adsorbing themselves on the metal’s surface and forming a protective film.

The different types of corrosion inhibitors include:

Anodic inhibitors – metal loss occurs at the anode, so it is important to protect it.
Cathodic inhibitors – by acting as sacrificial anodes, they protect the cathode by reacting themselves first, in place of iron or steel.
Mixed inhibitors – exhibit both anodic and cathodic protection from corrosion.
Volatile Corrosion Inhibitors (VCI) – mainly consist of amino salts or nitrile compounds, it forms a thin barrier on packaging surface to protect metal surfaces by preventing rust and corrosion.

What are the different types of scale inhibitors?

Scale inhibitors can coarsely be classified as organic and inorganic. The inorganic types include condensed phosphate, such as poly(metaphosphate)s or phosphate salts. Suitable organic scale inhibitors available are poly(acrylic) acid (PAA), phosphinocarboxylic acid, sulfonated polymers, and phosphonates. Phosphonates are maximally effective at high temperatures whereas sulfonated polymers are maximally effective at low temperatures. Copolymers that contain both phosphonate and sulfonate moieties can produce an enhanced scale inhibition over a range of temperatures.

Scale inhibitors can be classified into three main groups:

Thermodynamic inhibitors – complexing and chelating agents, suitable for specific scales.
Kinetic inhibitors – for hydrate formation may also be effective in preventing scale deposition.
Adherence inhibitors – surface active chemicals simply suppress the adherence of crystals to the metal surfaces.

Two ways by which the kinetic scale inhibitor operates are through adsorption effects and morphological changes of the growing sites. Due to adsorption effects, the inhibitor molecules occupy the nucleation sites which are preferred by the scale forming molecules. Thus, crystals cannot find active places to adhere to the surface and, therefore, crystal nucleation is not promoted. Conventional scale inhibitors are hydrophilic, which means they dissolve in water. It is desirable that the scale inhibitor is adsorbed on the rock to avoid washing out the chemical before it can act as desired. However, adsorption on the rock may change the surface tension and the wettability of the system. To overcome these disadvantages, oil soluble scale inhibitors have been developed.

What are some of the theories behind the mechanism of action?

The precise mechanism for scale inhibitors is not completely understood but the following are some of the theories. Scale inhibitors may adsorb onto the surface of the scale crystals just as they start to form. The inhibitors are large molecules that can envelop these microcrystals and hinder further growth. This is the primary mechanism. Many oil field chemicals are designed to operate at oil/water, liquid/gas, or solid/liquid interfaces. Since scale inhibitors must act at the interface between solid scale and water, it is not surprising that their performance can be upset by the presence of other surface-active chemicals that compete for the same interface. Before deployment it is important to examine in laboratory tests the performance of a scale inhibitor in the presence of other oil field chemicals. These chemicals function by delaying the growth of scale crystals, the inhibitor must be present before the onset of precipitation. Suspended solids also known as nonadherent scales are not acceptable. This suggests two basic rules in applying scale inhibitors:

The inhibitor must be added upstream of the problem area.
The inhibitor must be present in the scaling water on a continuous basis to stop the growth of each scale crystal as it precipitates.

Is there selection criteria of corrosion and scale inhibitors?

Compatibility – The scale inhibitor must not interfere nor be affected by other chemicals such as oxygen scavengers, corrosion inhibitors and biocides.
Application technique – this is the most important if the inhibitor is to be squeezed into the formation.
Severity of scaling – fewer products are effective at high scaling rates.
Efficiency – effective scale control at low inhibitor concentrations.
Balanced adsorption-desorption properties – allowing the chemicals to be slowly and homogeneously released into the production water.
High thermal stability – higher temperatures and required longer life limit the types of chemistry that are suitable.
Environmental considerations – Low toxicity and high biodegradability.
pH – most conventional scale inhibitors perform less effectively in a low-pH environment.
Viscosity – this is important when considering long umbilical applications such as in remote subsea fields.
Cost– sometimes the cheaper products prove to be the most cost effect, sometimes the more expensive products do.

What are the advantages of corrosion and scale inhibitors?

Provide corrosion inhibition in many types of closed recirculation systems
Prevent electrolytic corrosion
Protect against cavitation and erosion
Protect metal surfaces
Cost-effective, easy application and use
Offer improved performance
Help to reduce cleaning and maintenance costs
Improve reliability
Optimize operational efficiency

Are there limitations of corrosion and scale inhibitors?

Inorganic corrosion and scale inhibitors suffer hydrolysis and can precipitate as calcium phosphates because of temperature, pH, solution quality, concentration, phosphate type and presence of some enzymes.
Organic corrosion and scale inhibitors suffer hydrolysis with temperature, not effective at high calcium concentrations, must be applied in high doses.
Polymer-based corrosion and scale inhibitors have a limited calcium tolerance (ppm) although some can work at concentrations higher than ppm, larger concentrations are needed.
EDTA is expensive.

Where are some of the applications of corrosion and scale inhibitors?

To answer this, we first look at what how do inhibitors function to protect metal surfaces from corrosion? – they function in two ways:

They react with the substance or chemical that is the cause of interaction with the metal surface such as removing dissolved oxygen with a chemical reducing agent in solution or in a moist atmosphere.
They react with the metal to form a protective layer on the metal surface thereby preventing interaction between the corrosive chemical and the metal.

Some of the applications of corrosion and scale inhibitors include:

Closed-circuit heating and cooling systems.
Cooling tower water treatment.
Open recirculating cooling systems.
Boiler heat transfer surfaces.
Once through and potable water systems.
Carbon steel equipment in the oil and gas industry.

Corrosion and scale inhibition can take several forms depending on the circumstances of the metal being corroded. Proper monitoring and the elimination of vulnerable surface conditions, to avoid reactive metal combinations are all also part of effective corrosion reduction program. Corrosion and scaling occur as any other chemical reaction, i.e. under the right circumstances, but it can be slowed down using the right strategy of corrosion and scale inhibitors.

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REFERENCES

Chen et al. . Experimental and Electrochemical Research of an Efficient Corrosion and Scale Inhibitor. Materials (Basel). 12(11):.

Cooling System Scale & Corrosion Inhibitors. Retrieved 05/08/21.

Corrosion and Scale Control. Retrieved 05/08/21.

Corrosion & Scale Inhibitor: Cooling Water Treatment. Retrieved 05/08/21.

Corrosion and Scale Control for Cooling Water. Retrieved 05/08/21.

Mekarbane et al. . Development of Combined Corrosion and Scale Inhibitors. CORROSION Conference, Nashville, Tennessee, USA.

Scale Inhibitor. Retrieved 05/08/21.

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Scale Inhibitor. Retrieved 05/08/21.

How To Prevent Corrosion In Cooling Towers | B & V Chemicals

Water is used widely as a cooling medium in processes for many industries and public buildings. The use of a cooling tower or evaporative condenser is still the most effective method of removing heat from water used in a process. Inhibitors are used to prevent the build-up of scale and corrosion so the system can work effectively.

Back to basics; how do cooling towers work?

The heat is transferred from hot process fluids into the cooling water through a heat exchange surface; consequently, the cooling water heats up. The evaporation of a small percentage of this cooling causes the concentration of salts in the make up, then reduces the temperature of the cooling water, allowing it to be used for cooling again. Make-up water is used to replace the evaporated water.

Evaporative condensers are often used to cool closed systems whereby pipework containing hot process fluids is sprayed with water to remove heat from the system. The primary objectives in the design, operation and effective treatment of cooling water systems include improving efficiency in heat transfer, minimisation of energy and water usage, and safe, reliable operation.

When operating a cooling system, there are several considerations to ensure the achievement of these objectives, which include the control of scale, corrosion, fouling, and microbiological contamination.

Preventing scale in cooling towers

Scale is caused by the formation of insoluble calcium and magnesium salts and appears as a rock-like coating. If scale can form in heat exchangers and cooling tower packing, it will lead to a reduction in heat transfer and cooling capacity, as well as acting as a breeding ground for bacteria. As water is lost through evaporation, the concentration of dissolved salts and general airborne dust and debris within the system will increase.

If the system concentration can be limited to keep the hardness salts in solution, scale formation will not occur. In areas of the country where water hardness is high, it is necessary to use a water softener prior to use, to minimise the likelihood of scale build-up and to optimise water use within the system.

Unfortunately, the removal of hardness from the make-up water increases the corrosiveness of the water. There is a fine balance, in the chemical treatment of a cooling tower, to ensure that optimal scale and corrosion protection is achieved.

Using inhibitor chemicals to prevent scale

In many cases, scale inhibitor chemicals will be used which make the calcium/magnesium salts soluble, therefore preventing scale formation. The addition of acid (sulphuric) to lower the pH and alkalinity also reduces the potential for scale formation and is sometimes used as a means of scale control in larger cooling systems.

Scale inhibitors commonly used include:

Polyphosphate - Typically used in potable water systems. Provides good scale control under mild conditions but must be used correctly to prevent the formation of calcium phosphate deposits.
Phosphonates - Prevents scale by inhibiting crystal growth. Generally preferred to phosphates.
Acrylate Polymers - Modifies the crystal structure to prevent adhesion to heat transfer surfaces.
Copolymers (often having an acrylate and sulphonated functional group) - Function in a similar way to polyacrylates but can be more effective.

Preventing corrosion

Corrosion is the result of a chemical interaction between a material and its environment. In a cooling system, it results in the loss of metal from a surface, which may be pitting, and is often associated with the formation of deposits.

A simple representation of the corrosion process, an electrochemical reaction, in a cooling system is:

The schematic below uses iron as an example of a metal that corrodes but the basic principles apply to many metals/alloys
Iron (Fe) is lost from the anodic area into the water and is oxidised to Fe2+. The electrons released move to the cathodic area
Oxygen in the water reacts with these electrons to form hydroxide ions. Dissolved ions in the cooling water complete the electrochemical circuit back to the anode
Metal surfaces tend to have numerous irregularities which form the anodic/cathodic areas

Corrosion is accelerated by high levels of dissolved oxygen, particularly in conjunction with low pH (low alkalinity) although excessive alkalinity can also be a factor. Temperature and the number of dissolved solids are also factors.

When dissimilar metals and alloys come into contact, an electrochemical reaction, known as ‘galvanic corrosion', may also take place. The more reactive metal or alloy is the one that will corrode. In the following pairs of metals/alloys commonly found in cooling systems, the first one of the pair will corrode:

Steel and brass
Aluminium and steel
Zinc and steel
Zinc and brass

The pH and conductivity of water within the system are factors that also affect the rate of galvanic corrosion. Corrosion may also occur because of a chloride attack on stainless steel and microbial activity (microbial corrosion). Unfortunately, the conditions which are optimum to reduce scale formation are those likely to favour corrosion.