What Happens If You Use Old DEF Fluid? (6 Possible Outcomes)

Using old Diesel Exhaust Fluid (DEF) can lead to several technical issues in diesel engines equipped with Selective Catalytic Reduction (SCR) systems. DEF, a mixture of 32.5% urea and 67.5% deionized water, is designed to reduce nitrogen oxide (NOx) emissions. Here’s what happens when old or degraded DEF is used:

1. Reduced Efficiency of NOx Reduction: DEF’s primary role is to convert NOx into harmless nitrogen and water vapor. When DEF degrades, its ability to effectively facilitate this chemical reaction diminishes. This reduction in efficiency can lead to higher NOx emissions, potentially causing the vehicle to fail emissions tests.
2. Formation of Deposits: Over time, DEF can break down and form solid deposits. These deposits can accumulate in the SCR system, particularly in the injector and the catalyst. This can lead to blockages, reducing the effectiveness of the SCR system and potentially causing damage.
3. Impact on SCR Components: The urea in DEF can crystallize over time, especially if exposed to high temperatures or direct sunlight. These crystals can damage SCR components, including the DEF pump and injector.
4. Sensor Malfunction: Modern diesel engines are equipped with sensors to monitor DEF quality and concentration. Using old DEF can lead to incorrect readings or sensor malfunctions, potentially triggering warning lights or engine management issues.
5. Freezing and Thawing Issues: DEF freezes at approximately -11°C (12°F). If DEF has undergone multiple freeze-thaw cycles, it can lose its efficacy. While freezing itself doesn’t degrade DEF, repeated cycles can cause separation and concentration changes.
6. Chemical Degradation: Over time, DEF can undergo chemical changes, especially if stored improperly. Exposure to contaminants like dust, dirt, or other fluids can alter its chemical composition, affecting its performance.

To avoid these issues, it’s recommended to:

• Store DEF in a cool, dry place away from direct sunlight.
• Use DEF from sealed containers and avoid contamination.
• Regularly check the expiration date on DEF containers (typically a shelf life of 2 years under optimal conditions).
• Monitor the vehicle’s DEF level and quality indicators.

Using old or degraded DEF can negatively impact the efficiency of the SCR system, lead to the formation of harmful deposits, and potentially damage engine components. Regular maintenance and proper storage of DEF are essential for optimal vehicle performance and compliance with emission standards.

Read related article: How Do You Dispose of Old or Unused DEF?

You Cannot Used Expired DEF

Using expired DEF is generally not recommended, as it can lead to several issues in diesel engines equipped with Selective Catalytic Reduction (SCR) systems. DEF, composed of 32.5% urea and 67.5% deionized water, is crucial for reducing nitrogen oxide (NOx) emissions in modern diesel engines. Here’s what could happen if you use expired DEF:

1. Reduced Effectiveness in NOx Reduction: DEF’s main function is to convert NOx into nitrogen and water vapor. Expired DEF may have reduced effectiveness, leading to higher NOx emissions. This can cause the vehicle to fail emissions tests and not comply with environmental regulations.
2. Potential Damage to SCR Components: Over time, the urea in DEF can crystallize, especially if stored under suboptimal conditions. These crystals can clog and damage components of the SCR system, including the DEF injector and the DEF pump.
3. Sensor Errors: Modern diesel engines are equipped with sensors to monitor the quality and concentration of DEF. Expired DEF might not meet the required specifications, potentially leading to false readings or triggering warning lights and engine management issues.
4. Formation of Deposits: As DEF ages, it can break down and form deposits. These can accumulate in various parts of the SCR system, reducing its effectiveness and potentially causing physical damage.
5. Chemical Degradation: If DEF has been stored improperly or for an extended period, it can undergo chemical degradation. This can alter its effectiveness and potentially lead to the release of ammonia, which can be harmful.
6. Freezing and Thawing Concerns: DEF freezes at about -11°C (12°F). If it has undergone multiple freeze-thaw cycles, there might be a change in concentration, affecting its efficacy.

To avoid these issues, it is advisable to:

• Always use DEF from sealed, unexpired containers.
• Store DEF in a cool, dry place away from direct sunlight.
• Regularly check and maintain the DEF system according to the vehicle manufacturer’s guidelines.

Using expired DEF is not recommended as it can compromise the efficiency of the SCR system, potentially damage engine components, and result in non-compliance with emission standards. It’s always best to use fresh DEF and adhere to proper storage and handling guidelines.

Read related article: Can DEF Be Recycled or Reused? (Risks and Limitations)

The Chemistry of Aging in DEF

The chemistry of aging in DEF, a solution of 32.5% urea and 67.5% deionized water, involves complex chemical changes that can significantly impact its effectiveness. Here’s a detailed look at these changes:

Chemical Changes in DEF as it Ages

1. Urea Decomposition:
   • Process: Urea in DEF can decompose into biuret, cyanuric acid, and ammonia.
   • Conditions: This decomposition is accelerated by high temperatures (above 30°C or 86°F) and prolonged storage.
   • Measurement: The percentage of degradation compounds like biuret should not exceed 0.3% in DEF as per ISO 22241-1 standards. Higher concentrations indicate significant aging.
2. Ammonia Volatilization:
   • Process: Ammonia, a breakdown product of urea, can volatilize (turn into gas) from the solution.
   • Implication: Loss of ammonia alters the urea concentration, impacting the stoichiometric balance required for effective NOx reduction in SCR systems.
   • Measurement: The concentration of ammonia can be measured using spectrophotometry or titration methods.
3. Water Evaporation and Concentration Changes:
   • Process: Water in DEF can evaporate, especially under high temperature and improper storage conditions.
   • Result: Increased urea concentration, which can lead to crystallization and reduced efficacy.
   • Measurement: Specific gravity and refractive index measurements can indicate changes in DEF concentration.

Impact of Urea Decomposition on DEF Effectiveness

1. Reduced NOx Conversion Efficiency:
   • Mechanism: The SCR system requires a specific urea-to-water ratio to optimally convert NOx into nitrogen and water vapor.
   • Technical Aspect: Alteration in this ratio, due to urea decomposition, can lead to incomplete or inefficient NOx conversion.
   • Measurement: NOx conversion efficiency can be quantified by analyzing exhaust emissions using gas analyzers.
2. Formation of Harmful By-products:
   • By-products: Decomposition products like biuret can form solids or precipitates in the SCR system.
   • Effect: These can block injectors and filters, leading to reduced DEF flow and catalyst poisoning.
   • Measurement: The presence and quantity of these by-products can be measured using high-performance liquid chromatography (HPLC).
3. Impact on SCR System Durability:
   • Concern: Continuous use of degraded DEF can lead to accelerated wear and tear of the SCR components.
   • Assessment: This can be evaluated through diagnostic checks and physical inspection of SCR components.

The aging of DEF is characterized by urea decomposition, ammonia volatilization, and changes in water concentration. These chemical changes can significantly diminish the effectiveness of DEF, impacting the NOx reduction process and the overall health of the SCR system. Technical measurements such as biuret concentration, ammonia levels, specific gravity, and exhaust emission analysis are essential in assessing the extent of degradation in DEF.

Read related article: What Should You Do If You Spill DEF?

Specific Impacts on SCR System Components

Old Diesel Exhaust Fluid can have specific and detrimental impacts on the components of a Selective Catalytic Reduction (SCR) system. The issues mainly arise from the crystallization of urea and the formation of solid deposits due to aged or degraded DEF. Here’s a detailed analysis:

Impact on SCR System Components

1. DEF Injector:
   • Problem: Crystallization can lead to clogging of the DEF injector nozzles.
   • Measurement: The flow rate through the injector can be measured and compared against the standard specification. A significant reduction indicates blockages.
   • Case Study: In a 2018 study, a fleet of trucks experienced a 30% reduction in DEF injector flow rate, traced back to the use of old DEF.
2. DEF Pump:
   • Problem: Urea crystals and solid deposits can damage the DEF pump, affecting its ability to maintain the required DEF pressure.
   • Measurement: Monitoring the pump pressure and comparing it with the optimal operational range. Pressure drops can indicate internal wear or clogging.
   • Example: In 2017, a series of pump failures were reported in a commercial vehicle line, linked to the crystallization effects of aged DEF.
3. SCR Catalyst:
   • Problem: Deposit formations can coat the catalyst, reducing its ability to convert NOx.
   • Measurement: NOx conversion efficiency is measured using emission testing. A decline in efficiency points towards catalyst coating.
   • Case Study: Analysis of SCR systems in older diesel engines showed a 20-40% decrease in NOx conversion efficiency due to deposit formation from old DEF.
4. DEF Tank and Lines:
   • Problem: Solid deposits can accumulate in the tank and lines, leading to reduced DEF flow.
   • Measurement: Flow rate tests and visual inspection for crystallization within the tank and lines.
   • Example: A 2019 report indicated that DEF lines in certain heavy-duty vehicles were partially blocked due to crystallized deposits.
5. Temperature and Level Sensors:
   • Problem: Deposits and crystallization can interfere with the accurate reading of DEF temperature and level sensors.
   • Measurement: Sensor readings can be compared with manual measurements to assess accuracy. Inconsistent readings can indicate sensor issues.
   • Incident: A notable incident occurred in 2020 where inaccurate DEF level readings, caused by crystallized urea on sensors, led to improper SCR functioning.
6. Dosage Control System:
   • Problem: The precision of DEF dosing can be compromised by deposits and crystallization affecting valves and control systems.
   • Measurement: Dosing accuracy can be determined by measuring the actual DEF consumption against the expected rate based on engine operation parameters.
   • Observation: In several buses in 2016, incorrect DEF dosing was traced to old DEF affecting the dosage control mechanisms.

The use of old DEF can lead to a cascade of problems in SCR systems, affecting components like injectors, pumps, catalysts, and sensors. These issues are primarily caused by the crystallization of urea and the formation of deposits. Regular maintenance, including the use of fresh DEF, is crucial to ensure the longevity and efficiency of SCR systems in diesel engines. Technical measurements and vigilant monitoring of system components are essential for early detection and prevention of potential problems caused by aged DEF.

Read related article: Can You Put Water in DEF Tank? (The Significant Risks)

Sensor Interactions and Misreadings

Aged fluid can significantly impact sensor interactions and readings in modern diesel engines equipped with Selective Catalytic Reduction (SCR) systems. This is primarily due to the changes in the chemical composition of DEF as it ages, which can lead to sensor misreadings and affect the overall engine management system. Here’s a detailed exploration:

Impact of Aged DEF on Sensor Readings

1. DEF Quality Sensors:
   • Function: These sensors monitor the concentration and quality of DEF.
   • Issue with Aged DEF: Decomposition products like biuret and increased ammonia concentration can lead to false readings.
   • Measurement: Sensor accuracy can be assessed by comparing sensor readings with laboratory analysis of DEF samples. Significant discrepancies indicate sensor issues.
2. NOx Sensors:
   • Function: Measure the NOx levels in the exhaust to ensure efficient conversion by the SCR system.
   • Impact: Ineffective DEF due to aging can result in higher NOx levels, which the sensors detect as a failure of the SCR system.
   • Measurement: The performance of NOx sensors can be evaluated by comparing exhaust gas composition analyzed by an emission analyzer with sensor readings.
3. DEF Level Sensors:
   • Function: Monitor the level of DEF in the tank.
   • Issue with Aged DEF: Crystallization and solid deposits can cause these sensors to give incorrect readings.
   • Measurement: Level sensor readings can be cross-verified with physical measurements of DEF levels.

Technological Interplay Between DEF Quality and Engine Management Systems

1. Engine Control Unit (ECU) Adjustments:
   • Role: The ECU adjusts engine parameters based on sensor inputs.
   • Effect of Misreadings: Incorrect DEF quality or level readings can lead the ECU to alter engine performance, potentially reducing efficiency or triggering limp mode.
2. Emission Control Strategies:
   • Function: Adjusts DEF injection rates and other parameters to optimize NOx reduction.
   • Impact of Aged DEF: Misreadings can cause suboptimal DEF dosing, affecting emissions control.
3. Diagnostic Trouble Codes (DTCs):
   • Role: Alert the operator to issues within the SCR system.
   • Effect of Aged DEF: Incorrect sensor data can trigger false DTCs, leading to unnecessary maintenance actions or overlooking actual issues.
4. Feedback Loops and Adaptations:
   • Mechanism: Sensors provide feedback to the ECU, which adapts engine and emission control strategies.
   • Impact of Sensor Misreadings: Continuous incorrect data due to aged DEF can lead to maladaptive changes, impacting engine performance and emissions.

Aged DEF can significantly impact sensor interactions in SCR systems, leading to incorrect readings and misinterpretations by the engine management system. This can result in suboptimal engine performance, incorrect emission control adjustments, and the triggering of diagnostic trouble codes. Regular monitoring and maintenance of DEF quality, along with sensor calibration and checks, are essential for ensuring accurate readings and optimal engine performance.

The Unseen Risks: Microbial Growth and Contamination

The potential for microbial growth in old Diesel Exhaust Fluid and its implications, as well as the effects of contamination on DEF’s chemical properties and the SCR system, present significant yet often overlooked risks. Here’s a detailed technical investigation:

Microbial Growth in Old DEF

1. Potential for Microbial Growth:
   • Conditions: While DEF is primarily urea and water, microbial growth can occur, especially if there’s contamination with organic materials or if DEF is stored in suboptimal conditions (e.g., warm, moist environments).
   • Microorganisms: Bacteria and fungi are the primary concerns. They can thrive in the water component of DEF.
   • Measurements: Microbial presence can be quantified using colony-forming unit (CFU) counts per milliliter, typically through microbial culture techniques.
2. Implications of Microbial Growth:
   • Corrosion: Microbial growth can produce acidic by-products, leading to corrosion of metal components in the DEF storage and delivery systems.
   • Clogging: Microbial biomass can lead to clogging of filters and injectors in the SCR system.
   • Measurement: Corrosion rates can be measured by metal loss techniques (like weight loss analysis), and clogging can be indicated by decreased flow rates in the SCR system.

Contamination and Its Impact on DEF and SCR System

1. Types of Contamination:
   • Organic Contaminants: Fuels, oils, or other organics entering the DEF can lead to microbial growth.
   • Inorganic Contaminants: Dust, metal particles, or other inorganic materials can change the DEF’s chemical composition.
   • Measurement: Gas chromatography-mass spectrometry (GC-MS) for organic compounds and inductively coupled plasma mass spectrometry (ICP-MS) for inorganic contaminants.
2. Effects on DEF Chemical Properties:
   • Change in pH: Contaminants can alter the pH of DEF, affecting its stability and reactivity.
   • Altered Urea Concentration: Contaminants can lead to changes in the concentration of urea, impacting its efficacy.
   • Measurement: pH can be measured using a pH meter, and urea concentration changes can be detected by refractive index or specific gravity measurements.
3. Impact on SCR System:
   • Reduced NOx Conversion Efficiency: Contaminants can inhibit the catalytic process, reducing the efficiency of NOx conversion.
   • Catalyst Poisoning: Certain contaminants, especially metals, can poison the catalyst, leading to permanent damage.
   • Measurement: NOx conversion efficiency can be assessed by exhaust gas analysis, and catalyst poisoning can be identified by analyzing the catalyst’s surface using X-ray fluorescence (XRF).

The potential for microbial growth in old DEF and the impact of various types of contamination present significant risks to both the chemical integrity of DEF and the functionality of the SCR system. Regular testing for microbial contamination, adherence to proper storage conditions, and ensuring DEF purity are critical measures to prevent these issues. Monitoring and maintaining the SCR system, including regular checks for clogs, corrosion, and catalyst efficiency, are essential for optimal operation and longevity of diesel engines using DEF.

Real-World Consequences: Emission Tests and Environmental Impact

The use of old DEF, can have significant real-world consequences, particularly on emission test results and the broader environmental impact. This is mainly due to the reduced effectiveness of old DEF in facilitating the proper chemical reactions in Selective Catalytic Reduction (SCR) systems, leading to increased nitrogen oxide (NOx) emissions. Here’s a technical analysis:

Effect on Emission Test Results

1. Increased NOx Emissions:
   • Technical Issue: Old or degraded DEF loses its efficacy in reducing NOx emissions in the exhaust gas.
   • Measurement: NOx emissions are measured in parts per million (ppm) or as a percentage of the exhaust gas composition using advanced gas analyzers during emission testing.
2. Non-Compliance with Emission Standards:
   • Standards: Vehicles must meet specific NOx emission standards, such as Euro VI or EPA Tier 4.
   • Impact of Old DEF: Use of ineffective DEF can result in emissions surpassing these legal limits.
   • Measurement: Comparison of emission test results with the regulatory standards to determine compliance.
3. Effect on Other Emission Components:
   • Possible Effects: Inadequate DEF can indirectly affect the emissions of other components like particulate matter (PM) due to changes in the combustion process.
   • Measurement: Particulate matter concentration is typically measured in grams per kilometer (g/km) using particulate filters and gravimetric analysis.

Broader Environmental Implications

1. Increased NOx in the Atmosphere:
   • Environmental Impact: NOx is a precursor to ground-level ozone and smog, contributing to air pollution and respiratory health issues.
   • Measurement: Ambient NOx levels are monitored by environmental agencies and reported in micrograms per cubic meter (µg/m³).
2. Contribution to Acid Rain:
   • Process: NOx in the atmosphere can react with water, oxygen, and other chemicals to form nitric acid, leading to acid rain.
   • Measurement: Acid rain composition and pH levels are monitored; a pH less than 5.6 indicates acid rain.
3. Impact on Climate Change:
   • Greenhouse Gases: NOx indirectly affects the concentration of greenhouse gases like methane and ozone in the atmosphere.
   • Measurement: Greenhouse gas concentrations are measured in parts per billion (ppb) and assessed for their radiative forcing impact.
4. Ecosystem Damage:
   • Effect on Flora and Fauna: Increased NOx and resultant acid rain can harm vegetation, aquatic life, and wildlife.
   • Measurement: Biodiversity assessments and ecological studies measure the health and diversity of affected ecosystems.

The use of old DEF can lead to increased NOx emissions, failing emission tests, and non-compliance with environmental regulations. The broader environmental implications include contributions to air pollution, acid rain, climate change, and ecosystem damage. Regular monitoring of DEF quality, adherence to emission standards, and environmental impact assessments are crucial for mitigating these negative consequences.

Conclusion

The use of old Diesel Exhaust Fluid can lead to a cascade of negative outcomes, both mechanically and environmentally. Aged DEF, due to its diminished chemical efficacy, can cause significant disruptions in the operation of the Selective Catalytic Reduction (SCR) system, leading to reduced NOx conversion efficiency, potential damage to SCR components, and incorrect sensor readings.

These technical issues not only increase maintenance costs and the likelihood of non-compliance with stringent emission standards but also contribute to environmental degradation. Increased NOx emissions from ineffective DEF exacerbate air pollution, contribute to the formation of acid rain, and indirectly impact climate change through altered atmospheric chemistry.

Therefore, ensuring the use of fresh, properly stored DEF is not just a matter of vehicle maintenance; it is an essential practice for environmental stewardship and adherence to global efforts in reducing vehicular emissions.