The O2 sensor and you: Why you need it

Modern vehicles are much more complex than their predecessors. Numerous additions have been made to increase the fuel consumption, as well as to reduce the emissions. One of these things is the O2 sensor. All modern cars have at least one sensor, although most have two, and several have four sensors. These sensors are located at various points in the exhaust system and play an important role in both the consumption and emissions regulation.

For the tuner to O2 sensors to be in great pain in the butt. Individual pipes are a great way to power and performance to add your vehicle. Unfortunately, it is also not a place for your O2 sensors to see if you can not buy the right kind of tubes and headers. Typically, a sensor can be mounted on the exhaust manifold gasket (which by the header version) will be arranged at half the height of the exhaust pipe, usually just before the catalyst and the other.

Working together, the two sensor your fuel / air mixture, and EGR valve control. Without these sensors, your check engine light is lit, your car is running rough and reduce your fuel consumption clearly. In addition, it is (read impossible) pretty hard to pass an emissions test without installing O2 sensors. The pesky check engine light will usually give you away.

What to do O2 sensors? They tell your car's computer, the volume of unspent gases in your exhaust. According to this reading, your EGR (Exhaust Gas Recirculation) valve to open or close, so that these vapors to feed your engine and increasing fuel consumption. While tuners are not necessarily interested in the best gas mileage or reduce emissions, you still have these babies installed in order to pass your emissions test. Emission testing has been mandatory in most urban areas and even in many suburbs and rural areas.

In addition to the makes it impossible to pass the emissions test, the fact remains that the check engine light it difficult to know if another problem occurred. The check engine light is designed to illuminate under a variety of different conditions, from the sensor malfunction of the transmission problems and even loose gas cap (fuel leak sensor). The light can not turn off until you have installed the new O2 sensors. So, what do you do?

The best way to get around this problem, the headers and custom exhaust pipes with O2 sensor bungs already in place to buy. In this way, all you need to do is screw the sensors of the original pipes and install it in the new. The check engine light stays off and stay legally for testing purposes. O2 sensor removal requires a special socket, adapted to the diameter of the mother made in the sensor and slopes of the wiring harness in the leading vehicle. The dishes are usually found a short distance from the sensor, just follow the wire, and you will find it. In some vehicles, the wire ends are below the seats in cars, so be prepared.

O2 Sensor

O2 sensors are used in all cars made for the United States. They are used in cars made for many other countries as well. When the O2 sensor in your car goes bad, your car runs differently. This is a story of my experiences with the O2 sensor in my car. Your mileage may vary.

Update! See the bottom of the page for info on cars with multiple O2 sensors!

Background info:
Gasoline engines run best when the air-fuel mixture is correct. The air-fuel mixture must be controlled to reduce exhaust pollutant emissions. Lowest emissions are achieved with a slightly lean mixture. The catalytic converter, an essential part for emission control, also likes a controlled lean air-fuel mixture. The O2 sensor detects the air-fuel mixture of a gasoline engine by measuring the amount of oxygen in the exhaust gas. The fuel-injection system will trim the mixture richer or leaner based on the signal from the O2 sensor. The typical installation is in the exhaust manifold, where the hot exhaust gases will pass by it. High temperature(>350 C) is required for the sensor to operate. My car has a heated sensor, so the sensor starts to work very quickly after the engine has started. It has three wires. Two are for the heater, and one is the sensor output. The metal case of the sensor is grounded and is the return for the sensor's output. Unheated sensors have one or two wires. I do not know the exact composition of the sensor, but I do know how it is constructed and how it operates. A ceramic-like material is exposed to the exhaust gas on one side, and to the outside air on the other. A voltage is produced as oxygen travels through the material. A rich mixture will produce almost 900 millivolts. A lean mixture produces about 100 millivolts or less. The sensor does not produce in-between voltages with any regularity. I think the material in the sensor is made to match the optimum air-fuel mixture, and the output of the sensor is pretty much on or off(too rich or too lean). The car's fuel-injection system picks a voltage to compare with, and modifies the mixture to try to maintain an on-off ratio close to 50%, so if you averaged the voltage over time it would be about 400 or 450 mV. The on-off transitions occur about one or two times per second in my car when it's running properly. When the sensor is cold, no voltage is produced, and the sensor is an open circuit with almost infinite resistance. When the sensor heats up, the impedance drops and it can produce a little bit of current. If I had to guess, I'd say that mine has an impedance of about 5000 ohms when hot. The car presents a very high impedance load, in the megohms.

My car, and what it did:
The car is a Dodge Caravan, the engine is a Mitsubishi 3.0 liter V-6 with Holley multiport electronic fuel injection. At 100,000 miles(what a coincidence) the car started to run a little badly. A bit of hesitation, and some slight bucking at highway speeds. Full throttle performance was good. Exhaust was a bit smelly, both at idle and when driving. After a day or two of this, the "check engine" light would come on whenever the car had warmed up. I did check, and there was an engine :-) Fuel economy had slipped about 35 percent.

What the car says is happening:
Diagnostic codes can be read on my car by turning the key on-off-on-off-on and watching the "check engine" light for patterned blinking. The car reported a "51" which is "lean condition detected". Table of diagnostic codes. Fortunately, when my car was new I ran an extra wire when I was installing an alarm system and had to run wires from inside the car to the engine compartment, and I now attached this extra wire to the O2 sensor signal wire. Attaching a digital voltmeter inside the car to the wire and to ground showed that the oxygen sensor output never got above 250 mV, showing a lean condition. The car was compensating for this lean signal by running as rich as it possibly could.

Bench test:
Removing the sensor was easy, and I attached an ohmmeter to the sensor and found it to be infinite ohms. At this time I did not know that this was normal, so I went to the auto parts store and asked for a new O2 sensor. I had my ohmmeter with me, and tested the new sensor right there at the counter, under the apprehensive gaze of the counterperson. Many mechanics think that an O2 sensor can be damaged by an ohmmeter, but they are wrong. I found the new sensor also had infinite ohms, but bought it anyway. About $55.

Installation and road test:
Smooth as silk. Sensor output toggles up and down, the car runs better. It takes a couple of days before the car is running optimally. I hypothesize that the fuel-injection system has a group of mixture profiles for various operating conditions that are updated very slowly. All is well for 3 months, and I surf the web finding out information about O2 sensors to satisfy my curiosity.

When nice cars do bad things:
My car blows a head gasket. (See a picture of the motor torn apart. 60K bytes) After a long and expensive repair, I'm back on the road. Very soon I realize that my car is running less than perfectly, gas mileage is down, and it takes a lot more throttle to get it to go down the road. The transmission was shifting harder, and at higher engine speeds than it should. I suspect all sorts of things, mostly related to the major repair that just happened. Feeling like an O2 sensor specialist, I decide to check the output of the sensor to see what I can see. Very unusual results. Sometimes all appears to be well, other times the output is either on or off. The "check engine" light reports no codes. After a week of this I decide to take further action. I removed the O2 sensor and tested it by heating it with a propane torch while attached to a voltmeter. Voltage was produced as I moved the torch around the sensor, but I really couldn't make any judgement of the sensor based on this.

I build a simulator:
I couldn't figure out if the oxygen sensor or the fuel system was malfunctioning, so I decided to build a simulated O2 sensor to send signals to the car. This way I could vary the signals to see if the car responded in a predictable way. I also wanted to monitor the signal from the O2 sensor, to see if it responded in a manner consistent with the way the car was operating at any given time. I only had the one test wire run into the engine compartment, so I had to get clever to do both. I ended up with a setup that gave me a voltmeter to show the signal the car was getting, a switch that would give the car the signal from the O2 sensor or from my simulator, and a knob I could adjust the simulator's output infinitely from full lean to full rich. The simulator produced an on-off oscillating signal with a period of about one second. I made a web page for the simulator if you want to build one yourself. The link is further down the page.

Fooling the car:
The car responded well to the simulator. I could adjust the mixture while driving. I drove my workday commute for two days under the simulator. Since this was a dumb simulator, the mixture would eventually get too lean or too rich, and I'd have to crank the knob one way or the other until the car started running properly before moving the knob back somewhere near the middle. Flipping the switch over to monitor the O2 sensor was not giving me consistent results, but I was too busy with my commute and keeping the vehicle on the road to figure anything out. Finally I tried running while parked, looking at the output from the O2 sensor. It seemed to produce low voltage, but if I revved the engine really hard, the output would start toggling normally for a while. I took the O2 sensor out again and put the torch to it to clean it off. I noticed a rattling noise if I shook it, and upon close examination found that a piece of ceramic material was floating around inside the metal shield. I decided to try to return the sensor in exchange for a new one. Luckily I had saved the box the sensor came in. I also saved the old sensor, and had used its plug and wires as part of my simulator cable. The auto parts store replaced my sensor for free(because of the rattling sound). The engine runs fine again!

Two sensors in three months:
Upon close examination of the original sensor, I could see that the ceramic element was broken and wedged against the slotted metal cover. Both sensors actually had similar failures, but the replacement sensor failed in a way that still allowed it to function sometimes, and kept fault codes from appearing in the diagnostics. The hard shifting continued, however. I tracked that down to the kickdown linkage being assembled incorrectly when my head gaskets were replaced. At light pedal the transmission was sensing more throttle than it should have, so it waited longer and shifted harder.

Conclusions:

You spend a lot of time with your car, so pay attention to it because you must diagnose your car yourself. Cars are so complicated that a mechanic can't spend enough time with your car to properly diagnose it. The exception to this is a specialist or dealership, where a mechanic may have prior experience with your model car, or factory support. The disadvantage to this approach is that dealerships are always out to take as much of your money as possible, and are frequently dishonest. My approach is to find an honest mechanic who will honor my diagnosis and do the repair I suggest, or just do the repair myself.
Replacement parts are usually(but not always) lower quality than original parts. Save your receipts and packaging for the parts, it helps when you return them after they go bad.
Buy a service manual for your car, and learn how to read the fault codes out of the car's computer.
Whenever possible, earn an enormous amount of money so you can buy a new car every few years before trouble strikes. I’m still working on this one :)

Click to go to the O2 sensor simulator web page

Cars with multiple O2 sensors:
Starting around 1994, and definitely by 1996, all cars have multiple O2 sensors. There's one in the normal position between engine and catalytic converter, and another behind the catalytic converter. The engine control module monitors this extra one to verify the efficiency of the catalytic converter. With normal operation this O2 sensor produces almost no voltage because the catalytic converter gobbles up all the good stuff left in the exhaust.
I got a message from a fellow in Venezuela who had to remove his catalytic converters because they burned out, unleaded fuel being unavailable where he lived. The O2 sensors also failed (leaded fuel is bad for them, too). His car noticed, lit up lots of dash lights and ran poorly. He built an O2 sensor simulator, connected it to the front O2 sensors(I didn't say, but cars with dual exhaust have them in both pipes, so he had a total of four) and to the rear sensors. This didn't completely work, of course. The car thought the catalytic converters were bad since the signals were the same "after" as "before". I suggested he hook the O2 simulator only in place of the front sensors, and ground the rear sensors connections. I think that worked. You could also attenuate the O2 simulator signal with a couple of resistors and feed that to the car instead of the rear sensors, the front signal coming directly from the simulator.

Finally:
Using an O2 sensor simulator on a permanent basis isn't a solution, the simulator is not ideal since it needs constant adjusting. I only used it as a diagnostic aid and to limp around a little better when my O2 sensor was bad. It was quite valuable for that, and I learned a lot!

What is an O2 Sensor?

A lambda sensor also known as an O2 sensor is a device that is used to evaluate the amount of oxygen or (O2) in whatever liquid is being evaluated, it is also used to measure the level of oxygen in gas. In the latter part of the 1960s the O2 sensor was developed by Robert Bosch GmbH which is a Germany technology based company that supplies automobile mechanisms. The development was supervised by Dr. Gunter Bauman.

The original sensing component is made with a white crystalline oxide of zirconium material or Zirconia that is made into a thimble shaped coat on both sides. It came in both heated and unheated types with a light coating of platinum.

In 1998 the planar type o2 sensor was introduced. These lessened the use of the original ceramic sensing component. This is also when the heater was integrated and thus producing a more efficient and competent o2 sensor. Internal combustion engines in vehicles are engines that burns fuel to create mechanical energy, in these engines there needs to be a perfect balance of fuel and oxygen. This is where the use of O2 sensors is most common.

In addition to being used in automobiles o2 sensors are also in diving equipment, the sensor is used to determine the partial pressure of oxygen in the mixture of gaseous chemicals that the divers use for respiration. The partial pressure refers to the level of pressure that the oxygen would have engaged had it been the only gas in the tank.

O2 sensors are also used in respirators; these are usually masks that are intended to filter the air intake or to provide a fresh supply of oxygen. Oxygen analysers additionally incorporates o2 sensors, they are commonly used in the medical field for the purpose of anesthesia monitors as well as oxygen concentrators. O2 sensors are mainly used in three types of technology; they are automotive technology, Diving technology and scientific technology.

In the automotive applications an o2 sensor is used mainly within the engine to regulate fuel injection and emissions. Within the Diving technology the O2 sensor is used to analyse the application of what is called breathing gas. The scientific application consists of the use of O2 sensors in marine biology which is the study of sea life.

Within this field the sensor is used to measure respiratory patterns of different kind of sea life. In addition to marine biology, o2 sensors are also used as electrodes and oxygen opt odes wherein the electrode is used to measure oxygen on a platinum surface. And the opt ode is used to optically measure the focus of oxygen. In essence oxygen can be measured in numerous ways; however the more popular is through the use of O2 sensors.

Symptoms of defective O2 sensor

The O2 sensor eventually needs to be replaced in all vehicles. But how would you know if the O2 sensor has gone bad? There are signs you should look for to diagnose a faulty sensor.

The O2 sensor as it is commonly called plays an important role in monitoring the oxygen content of the car's exhaust system. It determines the optimal mixture of air to fuel ratio needed to run the vehicle. A defective sensor can greatly affect your vehicle's fuel consumption because it allows the vehicle to use more fuel than what it should. Hence faulty sensors need to be diagnosed and replaced promptly.

But determining if the O2 sensor is really defective will need accurate diagnosis. Let's see what are the symptoms of a faulty O2 sensor:

1] The symptoms of a faulty O2 sensor starts with sudden decrease in vehicle's gas mileage (the vehicle starts consuming more gas than usual). A defective sensor makes the air-fuel mixture to run too rich or too lean resulting in poor fuel economy.
2] The defective O2 sensor also shows up as a check engine light or malfunction indicator lamp illuminating in the vehicle's dash board. But this can happen due to many other reasons (defective oxygen sensor being one of them).
3] Perhaps the most accurate diagnosis of a defective O2 sensor can be done using an OBDII code checker. The OBDII code checker is capable to identifying the defects in the exhaust system of the car including identify a fault O2 sensor. Please note that only cars made in 1996 and after are equipped with OBDII interface. OBDII code reader will generate a diagnostic trouble code that can indicate with specific O2 sensor has gone bad.
4] Smog test failures can also be an indication of a failed oxygen sensor. EPA (Environmental Protection Agency) and CARB (California Air Resource Board) 50 to 60% of all smog test / emission test related failures are attributed to the defective O2 sensor. Faulty O2 sensor leads to either low or high CO emissions in the smog tests.

Since proper functioning O2 sensors are vital for the optimal fuel consumption in the car, its best to replace the faulty sensor when in doubt.

Following are the guidelines you can use for replacing the O2 sensors in your vehicle:
A] The unheated 1 or 2 wire O2 sensors, used in vehicles from mid-1970s through early 1990s should be replaced every 40,000 to 50,000 miles.
B] Heated 3 and 4 wire O2 sensors, used in the vehicles from mid-1980s through mid-1990s should be replaced every 60,000 to 70,000 miles.
C] Newer vehicles made in mid-1990s and later, recommend replacing the O2 sensors every 100,000 miles.

NTK O2 Sensors

NTK is the world’s largest supplier and manufacturer of original equipment O2 sensors. NTK O2 Sensors combines expertise with innovation and delivers O2 Sensors with superior fit, form and function. When you require the best, count on NTK Oxygen Sensors to deliver.

O2 Sensors are used in modern automobiles to control the fuel and ignition systems to optimize a car's performance in the areas of emissions and fuel economy. Sensors are located before and after the catalytic converter to check on the amount of oxygen in the exhaust. The sensor sends signals to the car's on-board computer, which then can adjust several variables, including air/fuel ratio and timing, in order to bring the engine into the optimum operating range.

OEM QUALITY AND RELIABILITY

Each NTK O2 Sensor is:

Extensively Tested During Manufacture to Guarantee Quality and Reliability
Supplied With a Factory-Fitted OEM Connector for Easy Installation
Precision manufactured with a sensing element incorporating NTK's premier technical ceramics

O2 sensors should be tested at each tune-up. Failed or worn out O2 sensors can cause:

Failed Emission Tests
Increased Fuel Consumption
Failed Catalytic Converters
Poor Driveability
Increased Emissions

When to Replace O2 Sensors in Your Car or Truck

What is an O2 sensor? In the simplest form, it is a sensor that measures oxygen. In a more complex form it accomplishes much more than this. Its role is to provide the engine computer in your car or truck with accurate measurements of the levels of oxygen in the exhaust. Accurate data is important, as this data is used to determine the perfect oxygen to fuel for your vehicle's engine. Without accurate data, a failing O2 sensor can have a negative impact on your vehicle's overall performance.

So this begs the question of when to replace an O2 sensor in your car or truck. Should you wait until the check engine light turns on, or should you take preventative measures and change the part before it completely fails. How you handle this situation is probably going to reflect your personality. If you are a procrastinator, you will more than likely just wait until the part fails and the check engine light comes on. If you tend to fix things ahead of time to save yourself future grief, you will more than likely replace the part before it fails.

Although both options are feasible, taking preventative measures should win out in the end. Most car manufacturers suggest replacing your vehicle's O2 sensor between 60,000 and 90,000 miles in order to keep your vehicle's engine operating at optimal performance. This is because a failing O2 sensor will give inaccurate readings to your engine's computer, which will create an improper air to fuel mixture. Having a fuel to air mixture that doesn't meet your vehicle requirements will lead to excess fuel consumption, as it will create a mixture that has too little or too much oxygen it it. It also leads to excess wear and tear as your vehicle's exhaust system is forced to work under harder circumstances. Also, your vehicle will release higher levels of pollutants into the environment as a result of an improper mixture.

Replacing an O2 sensor is considered a simple automotive repair job for intermediate mechanics. If you aren't certain on how to change an O2 sensor, just bring your vehicle to your nearest mechanic and they will be able to replace it for you. Now that you know some of the negative side effects of a failing O2 sensor, you can make your own informed decision on when to replace the O2 sensor in your car or truck.

Jordan Mulligan works in the Aftermarket Auto Parts Industry for Prime Choice Auto Parts. Prime Choice prides itself as a manufacturer and distributor of high quality aftermarket auto parts. For More Info: When to Replace O2 Sensors.

Evaluating a Bad Lexus O2 Sensor and Its Replacement

An O2 sensor is an electronic mechanism that calculates the quantity of oxygen in the gas or liquid being examined. It is a tool that detects the quantity of oxygen in the exhaust stream and transfers that information the ECM for appropriate fuel control. Used with a response system to sense the existence of oxygen in the exhaust gas and indicates the computer which could use the voltage signal to verify engine operating competence and regulate the air or fuel ratio.

The O2 sensor is usually located in the exhaust manifold. The one end of o2 sensor distinguishes the levels of not burned combustibles in the exhaust stream, and the other end attaches to wiring that transmits the information to the computer. The computer then utilizes the sensor analysis to guarantee that the engine is being given the accurate quantity of fuel. The readings from the o2 sensor will change if extra or insufficient fuel is used, which will prompt the computer to re change the quantities of fuel being transported to the engine. An O2 sensor will be unsuccessful periodically. Significant response about engine performance will be gone when the sensor goes wrongs. Therefore, the computer that runs the electronic fuel injection scheme will have no thought how much fuel to transport to the engine.

Evaluation of O2 Sensor

An O2 sensor will occasionally have a mileage evaluation, which specifies the period that the O2 sensor is likely to last. There are several ways to find this information. A car owners handbook or supermarket handbook should affirm the estimated duration of its O2 sensor. The dealership could search for the estimated duration of an O2 sensor for a particular car if these books are unavailable. Various aftermarket auto parts supplies have alike information. Its not required to wait until the sensor fails to change it to sustain peak engine performance. Several experts now advise replacing Lexus O2 Sensor at exact mileage times for defensive maintenance. The suggested gap for unheated one or two wire O2 sensors on 1976 through early 1990s applications is every 30,000 to 50,000 miles. Warmed three- and four-wire O2 sensors on mid-1980s through mid-1990s functions could be modified every 60,000 miles. The suggested replacement gap is 100,000 miles on 1996 and newer OBD2 automobiles.

Automotive sensors, conference recognized as dioxide sensors, create new electronic fuel injection and emission control probable. They help verify if the air fuel ratio of a burning engine is loaded or lean. As O2 sensors are situated in the exhaust way, they do not directly calculate the air or the fuel incoming the engine. It can be used to indirectly verify the air-to-fuel percentage when data from o2 sensors is joined with information from other sources. Closed-loop feedback-managed fuel injection contrasts the fuel injector yield according to real-time sensor information rather than working with a predetermined fuel plot. Additionally to allowing electronic fuel injection to operate capably, this emissions manage technique could decrease the quantities of both unburnt fuel and oxides of nitrogen from incoming the atmosphere.

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