Kristy Gillette Cortec Corporation

Kristy Gillette Cortec Corporation
VpCI Chemistry 101 Kristy Gillette Cortec Corporation

as natural as water flowing downhill
CORROSION Natural process as natural as water flowing downhill

Corrosion Corrosion inhibitors

Outline Corrosion Corrosion Prevention Corrosion Inhibitors
Vapor-phase Corrosion Inhibitors (VpCI) Cortec’s VpCIs Conclusions

Corrosion Cost in the US
(Billions of Current Dollars) All Industries Total Avoidable Motor Vehicles Total Avoidable Aircraft Total Avoidable Other Industries Total Avoidable Sources: Economic Effects of Metallic Corrosion in the United States, 1978. Cost of Corrosion and Preventative Strategies in the United States, 1998.

Defining Corrosion Definition: Examples of Corrosion:
The destruction, degradation or deterioration of material due to the reaction between the material and its environment For metals, this is a natural process by which a metal attempts to revert back to its original state by releasing energy. Natural iron is oxidized, we add energy when we mine it - iron wants to return to a natural, low energy state Examples of Corrosion: Cavities in teeth Batteries Red rust, white rust, metallic corrosion…

Corrosion Appearance Classification by appearance (8 categories)

Corrosive Environments
Moist air is more corrosive than dry air Hot air is more corrosive than cold air Hot water is more corrosive than cold water Polluted air is more corrosive than clean air Acids are more corrosive than bases (alkalies) Salt Water is more corrosive than fresh water Stainless steel will outlast ordinary steel No corrosion will occur in a vacuum, even at very high temperatures, etc.

The Corrosion Cell Oxidation Reduction Current Flow Anode Cathode
Electronic Path

Corrosion Prevention Materials selection (more resistant metal)
Coatings (metallic, organic) Design (eliminate dead spaces, crevices) Cathodic and anodic protection (potential) Alteration of environment Corrosion inhibitors

Benefits of Corrosion Control
Reduce corrosion costs lower maintenance and repair costs extended useful lives of equipment and buildings reduction of or reduced product loss from corrosion damage

Benefits of Corrosion Control
Lower risk of failure safety product liability avoidance of regulation loss of goodwill

Corrosion Inhibitors

Corrosion Inhibitor Classification
Anodic (nitrites) Cathodic (arsenic, bismuth, antimony) Precipitation (silicates, phosphates) Organic/Filming (amines, sulfonates) Vapor-phase

Vapor-Phase Corrosion Inhibitors
Definition: Vapor-phase corrosion inhibitors condition an enclosed atmosphere with a protective vapor that condenses on all metal surfaces (including recessed areas, cavities) A multi-metal corrosion inhibitor that protects in 3 phases- contact, vapor and interphase Practical: Prevents corrosion, even if not in direct contact allowing cost effective, easy application, use and disposal. Clean, dry and effective protection.

Vapor-Phase Corrosion Inhibitors History
Late 1900s Discovery Late 1940s US Navy (boilers, piping systems) 1950s Begins New Research 1977 Start of the Cortec Corporation

Vapor-Phase Corrosion Inhibitors Applications
Process Industry Construction Electronics Transportation Steel Industry Military

How Do VpCIs Work? Corrosion inhibiting molecules are emitted from their source Molecules naturally diffuse from the source toward the metal Molecules are adsorbed forming a protective film on metal Film protects metal from corrosion

VpCIs Effectiveness Factors
Vapor Pressure Diffusion Evaporation/Sublimation Rates Chemical Composition Environmental Factors Temperature, Air Flow, Humidity, Cleanliness

Vapor Pressure Definition:
The pressure exerted when a solid or liquid is in equilibrium with its own vapor. The vapor pressure is a function of the substance and of the temperature

Vapor Pressure Explained
Vapor pressure reflects HOW MUCH of a substance is required to reach saturation  low VP means a small amount is required  high VP means a large amount is required VpCI vapor pressure is lower than water, therefore, given a specific air space (package or enclosure), only a small quantity of VpCI is required to counteract the effects of a relatively large quantity of moisture vapor.

Vapor Pressure Examples
Atmospheric pressure: 760 mm Hg Water: 18 mm Hg at 68ºF (20ºC) Typical VpCI: 10-4 mm Hg at 68ºF (20ºC) Sodium nitrite: ~ nil

Diffusion Governed by Fick’s Law
Natural process by which VpCI molecules travel from an area of high VpCI concentration to an area of low VpCI concentration until equilibrium is reached Examples: In cell biology, diffusion is the main form of transport for necessary materials through cells (amino acids, ion transport, etc…) Deflation of helium balloon Aroma of fresh baked cookies diffuses through the kitchen/home

Diffusion Analogies Like an air-freshener in your car, VpCI travels from the “source” where there is a high concentration… to all void spaces (low concentration) until all the air is saturated with VpCI molecules.

Evaporation & Sublimation Rates
Determines how quickly saturation occurs Evaporation (Liquid  Gas) Determines how quickly molecules are released. Different substances will release gaseous molecules at different rates. Too fast may mean not long enough protection Too slow may mean no protection achieved Sublimation (Solid  Gas) Same as above, but think about VpCI powder, which is a solid, but emits a vapor.

Chemical Composition VpCI molecules are “polar” meaning they are attracted to metal, rather than just passing past the metal. VpCI molecules adsorb onto metal surfaces Adsorption = accumulation of atoms/molecules onto the surface Absorption = diffusion of molecules into a liquid or solid

Environmental Factors
Temperature The higher the temperature, the higher the vapor pressure Hot air is more corrosive than cold Air Flow Accelerates the depletion of VpCIs Humidity Moisture is corrosive. Requires excess VpCI to combat the acts of moisture. Cleanliness Contamination causes corrosion Oils and dirt act as barrier to VpCIs

Putting It All Together
VpCI products emit a protective vapor that adsorbs onto multi-metal surfaces, protecting both the anode and cathode. Quantity to reach saturation = Vapor Pressure Ability to travel to recessed areas = Diffusion How quickly molecules go into vapor phase = Evaporation/Sublimation rate

Vapor-Phase Corrosion Inhibitors Benefits
Cost effectiveness (VpCI vs. barrier bags + desiccants) Ease of use (recessed areas) Cleanliness (thin layer) Safety/Environment (LD50)

Toxicity * LD50 =mg of chemical per kg of rat weight which kills 50% of the population

Cortec’s VpCIs Multi-metal protection (VpCI-126)
Multi-functional (VpCI-125, VpCI-377) Very low toxicity (VpCI-309) Environmental friendly (ISO 14001) Superior quality system (ISO 9001)

Test Methods Vapor Inhibiting Ability VIA (Fed. Std. 101C) Razorblade
Half Immersion Test Electro-Chemical Polarization Resistance, Tafel Plots, etc. SO2 and F-12 Others Accelerated corrosion testing (humidity, salt spray, QUV, etc…)

VIA Test SO2 Test Razorblade Test F12 Test

Important Parameters Of Use
Surface cleanliness Surface finish Conditioning Contaminants Source exhaustion Others

Defining Performance Protection Conditions Long/short term
Distance from source Conditions Humidity Temperature Corrosive agents, contaminants

Conclusions Corrosion Corrosion prevention Corrosion inhibitors
Vapor-phase corrosion inhibitors Cortec’s VpCIs

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