ADCERAX® Zirconia Oxygen Sensor Chip is engineered using a solid electrolyte made of yttria-stabilized zirconia, which enables oxygen ion conduction at elevated temperatures. This conduction mechanism generates an electromotive force in response to oxygen concentration differences across the ceramic element, providing precise measurement capability. By translating this signal into real-time data, the chip supports critical control of air–fuel ratios in combustion systems, improving fuel efficiency and reducing harmful emissions.
Performance Features of Zirconia Oxygen Sensor Chip
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Withstands up to 900 °C continuously
The chip’s yttria-stabilized zirconia substrate maintains full oxygen ion conductivity in environments reaching 900 °C, ensuring signal stability in exhaust systems. Thermal cycling resistance has been tested to exceed 1,000 cycles between 200 °C and 850 °C without structural degradation.
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Maintains structural integrity during rapid heating
Material phase stability under abrupt temperature rise has been verified through thermal shock tests, where samples endured a ΔT > 600 °C shift within 60 seconds with no visible cracks or delamination.
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Suitable for combustion systems with fluctuating temperatures
In field simulations for industrial furnaces, the chip retained operational accuracy after 1,500 hours of exposure to variable heat zones between 400 °C and 850 °C, showing less than ±2% signal drift.
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Ignition time under 15 seconds
The embedded heater reaches operational temperature in <15 s, accelerating sensor readiness during cold engine start or intermittent furnace cycling.
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Rapid signal transition within milliseconds
Dynamic step-change tests from λ=0.9 to λ=1.1 demonstrated signal response from 600 mV to 300 mV in <150 ms, ensuring real-time air–fuel adjustment accuracy.
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Low power demand for high efficiency
The integrated heater operates within a rated power envelope of <6 W, reducing thermal load on control circuits and enabling use in compact sensor modules.
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Resists degradation from lead, sulfur, and silicon
The sensor element sustained over 2,000 hours of exposure to synthetic flue gas with 50 ppm SO₂ and 10 ppm Pb, showing <5% signal deviation.
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Stable internal resistance over prolonged operation
Measurements indicate internal resistance below 1.0 kΩ at 850 °C across a 3,000-hour continuous test, maintaining low signal noise and high repeatability.
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Anti-aging stability supports long-term deployment
Simulated lifecycle testing under high humidity and corrosive gas confirmed a service life exceeding 5 years in industrial kiln environments with minimal recalibration intervals.
Technical Properties of Zirconia Oxygen Sensor Chip
The Zirconia Oxygen Sensor Chip is engineered to operate reliably in high-temperature, chemically aggressive environments where stability, responsiveness, and endurance are critical. Its ionic conduction properties, thermal resilience, and integrated heating structure enable precise and long-term oxygen detection in combustion control and exhaust monitoring systems.
| Property |
Specification |
| Core Material |
Yttria-Stabilized Zirconia (YSZ) |
| Max Continuous Operating Temp. |
900 °C |
| Oxygen Measurement Range |
0.1% – 100% O₂ |
| Response Time (T90) |
<150 ms (λ step) |
| Heater Ignition Time |
<15 s to operating temp |
| Heater Power Consumption |
<6 W nominal |
| Internal Resistance @ 850 °C |
≤0.5 kΩ |
| Electrode Coating |
Platinum-based conductive layer |
| Anti-Poisoning Resistance |
Lead/Sulfur resistant, tested >2000 hrs in SO₂ exposure |
| Thermal Shock Resistance |
Withstands ΔT >600 °C per cycle |
| Drift Stability After 1500 hrs |
<±2% signal deviation |
| Expected Service Life |
>5 years under industrial conditions |
Specifications of Zirconia Oxygen Sensor Chip
Packaging of Zirconia Oxygen Sensor Chip
Zirconia Oxygen Sensor Chip is engineered with a solid-state yttria-stabilized zirconia electrolyte that enables oxygen ion conduction at high temperatures. This mechanism generates a stable electromotive force when a differential in oxygen concentration exists, allowing real-time feedback of exhaust gas composition. By delivering fast and accurate λ control, it plays a critical role in optimizing fuel injection, reducing emissions, and improving combustion efficiency in advanced engine systems.
Enhancing Real-Time Combustion Control in Demanding Automotive Systems with ADCERAX® Zirconia Oxygen Sensor Chip
The Zirconia Oxygen Sensor Chip from ADCERAX® plays a vital role in closed-loop air–fuel ratio control, particularly under extreme conditions such as high exhaust temperatures, rapid throttle response, and fuel composition variability. By ensuring precise λ regulation, this chip supports emission reduction and combustion efficiency across advanced automotive and off-road platforms. The following application challenges highlight how its technical properties align with real-world automotive demands.
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High-Temperature λ Sensing in Gasoline Direct Injection (GDI) Turbo Engines
✅Key Advantages
1. High Thermal Stability at Exhaust Temperatures up to 900 °C
The YSZ electrolyte maintains oxygen ion conductivity without lattice degradation when positioned near the exhaust manifold. Performance testing under 850–900 °C continuous exposure showed <2% signal drift over extended operation.
2. Fast λ Transition Response (<150 ms under load change)
Rapid EMF signal stabilization enables the ECU to correct fuel injection during throttle transients and knock avoidance phases. This prevents over-enrichment during boost recovery and improves combustion efficiency in high-load, high-RPM events.
3. Platinum-Based Anti-Poisoning Electrode Layers
Electrode coatings maintain electrochemical activity under SO₂, Pb, and silicon compound exposure common in modern fuel blends. This reduces signal decay that typically forces recalibration or premature probe replacement.
✅ ️Problem Solved
In multiple GDI engine validation cycles, standard planar sensors placed upstream of the catalyst experienced signal lag and drift after 500–800 operational hours, particularly during wide-open throttle accelerations. This caused inconsistent λ feedback and intermittent ECU enrichment lockout events. By contrast, ADCERAX® Zirconia Oxygen Sensor Chip maintained consistent voltage output after 1,500+ hours at 850–900 °C, allowing stable closed‑loop combustion control and preventing emission threshold exceedances. This directly reduced corrective recalibration frequency and avoided power derating events associated with ECU fallback strategies.
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Oxygen Feedback in Hybrid Regenerative Braking Recovery Modes
✅Key Advantages
1. Ignition Readiness in <15 Seconds After Engine Restart
The integrated heater rapidly elevates the sensing interface to ionic conduction temperature following hybrid stop phases. This prevents prolonged open‑loop operation during catalyst re‑light conditions.
2. Low Heater Power Demand (<6 W)
The heater is optimized for energy‑limited hybrid systems where auxiliary power draw must be minimized. This ensures reliable λ sensing without compromising battery allocation for traction systems.
3. Stable Output Signal After Frequent Stop‑Start Cycling
Internal resistance remains consistent across repeated thermal cycling, preventing λ drift. Testing demonstrated <±1.5% signal shift after 10,000 stop‑start cycles.
✅ ️Problem Solved
In hybrid platforms with aggressive stop‑start frequency, conventional oxygen sensors show delayed re‑activation that prolongs open‑loop fueling, resulting in elevated cold‑start emissions and fuel penalty. Field-testing in a hybrid urban drive cycle scenario showed that ADCERAX® Zirconia Oxygen Sensor Chip restored closed‑loop control ~8–12 seconds faster than standard alternatives, reducing transient HC and CO spikes during catalyst warm-up and improving real‑world fuel efficiency. This ensures consistent emission compliance even under dense traffic stop‑start conditions.
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Oxygen Feedback Regulation in Lean-Burn Commercial Gasoline Engines
✅Key Advantages
1. Fast Thermal Activation Below 3 Seconds
Integrated heater design enables sensor stabilization in <3 s, even during cold urban start cycles. This minimizes delay in closed-loop control activation.
2. Wide Lambda Accuracy Window
Maintains sensing precision across a λ range from 0.8 to 2.0, critical for lean-to-rich transitions during acceleration bursts and idle-stop recovery phases.
3. Soot-Resistant Platinum Electrode Layer
Engineered to resist carbon accumulation in low-load cruising, preventing long-term drift. Field-tested in fleet vehicles across 100,000 km operation.
✅ ️Problem Solved
Lean-burn systems demand stable lambda control despite temperature swings and intermittent combustion patterns. Conventional sensors often fail to deliver consistent feedback below 400 °C exhaust temps, resulting in fuel trim errors and emissions spikes during idle-heavy cycles. ADCERAX® Zirconia Oxygen Sensor Chip ensures reliable signal generation even during cold-start and deceleration phases, enabling smoother ECU modulation and up to 12% fuel efficiency gains without compromising emissions compliance.
Operational Best Practices for Installing and Maintaining ADCERAX® Zirconia Oxygen Sensor Chip
The ADCERAX® Zirconia Oxygen Sensor Chip is a precision ceramic sensing component designed for closed-loop combustion systems. To ensure stable long-term performance, accurate output signals, and proper integration with ECU or controller units, users should follow a structured set of handling, installation, and maintenance practices.
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Pre-Installation Inspection and Handling Guidelines
1. Inspect all chips for surface cleanliness and visible integrity
Before assembly, check for flatness, hairline cracks, or electrode contamination on the ceramic surface. Any visual defect could lead to voltage output instability or early-life failure in operation. Ensure breathing holes are clear and unobstructed by dust, packaging residue, or manufacturing debris.
2. Store in clean, dry, and static-free environments before use
Unused chips should be sealed in anti-static pouches, away from moisture and direct sunlight. Store at ambient temperatures of 10–30 °C to avoid pre-aging of the ceramic or electrode surface. Avoid stacking bare chips or applying pressure on corners.
3. Handle only with non-metallic tools or ESD-compliant tweezers
Contact with metal tools can cause microfractures or surface contamination. Always use ceramic-tipped or ESD-safe tools during inspection or positioning. Operators should wear grounded wrist straps to prevent static discharge damage.
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Installation into Sensor Modules or Housing Assemblies
1. Apply uniform pressure during mounting to prevent ceramic stress
Do not use excessive torque when fixing the chip into probe or module housings. Uneven force can lead to structural damage or long-term microcrack propagation. Use validated alignment fixtures if possible.
2. Ensure correct orientation of signal and heater terminals
Follow the customer-supplied or ADCERAX-recommended wiring diagram when connecting to the ECU or signal processing board. Miswiring the heater circuit or reversing signal polarity can lead to startup failure or irreversible damage.
3. Avoid direct contact with flame or aggressive gas jets
While the chip tolerates high temperatures, direct flame impingement or turbulent burner contact can exceed its thermal gradient limits. Maintain a minimum distance of 20 mm from flame core zones in combustion chambers.
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Operating Environment and Sensor Startup Procedure
1. Ramp up temperature using controller-based heater activation
Avoid cold shock by gradually heating the chip using its integrated low-power heater via controlled current regulation. Heater voltage must not exceed specified peak values (typically under 12 V DC) during ignition.
2. Avoid exposure to high humidity or corrosive vapors during warm-up
Initial activation must be performed in a dry, clean air atmosphere. Presence of condensation, coolant vapor, or fuel mist during startup can cause electrode delamination or short-circuiting.
3. Maintain proper exhaust flow across the sensing surface
Stable oxygen readings require laminar gas flow without pulsation. Avoid placing the chip in zones of reverse flow, eddy formation, or low-velocity stagnation, as this leads to signal fluctuation and control errors.
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Long-Term Maintenance and Troubleshooting Tips
1. Inspect signal stability and heater current at regular intervals
Over time, monitor for drift in EMF output or heater current beyond expected values. Significant variation could indicate partial fouling or degradation and requires evaluation against baseline specs.
2. Avoid cleaning with high-pressure air or aggressive solvents
Cleaning procedures must be gentle; use low-pressure dry air to remove soot. Do not use alcohols, acetone, or acidic cleaners, which can chemically attack the platinum electrodes.
3. Replace after rated service life or if deviation exceeds tolerance
The ADCERAX® Zirconia Oxygen Sensor Chip is rated for >5 years or 2,000+ operational hours, depending on application severity. Replace if signal error exceeds ±5% under calibrated gas or if heater fails to reach setpoint temperature.
