Diagnose Engine Surges, Stalls, Misfires, Power Loss

Mass Air Flow Sensor failure symptoms

1. Low gas mileage, shuddering, stalling, knocking or pinging.
2. Check engine light may illuminate on the instrument panel.

Crankshaft Position Sensor failure symptoms

1. Engine may start normally in some cases, but will cut off after a few minutes (or seconds) of operation.
2. Engine may be unable to start at all.
3. No spark from the spark plugs.
4. Engine may experience backfiring or irregular rpm function, if the vehicle starts at all.
5. Long cranking time when starting cold
6. Engine may run rough on an intermittent basis, poor idle, poor acceleration, stumbling and/or hesitation.
7. Drop in mileage and stalling upon acceleration.

Camshaft Position Sensor failure symptoms

1. Engine may start normally in some cases, but will cut off after a few minutes (or seconds) of operation.
2. Engine may be unable to start at all.
3. No spark from the spark plugs.
4. Engine may experience backfiring or irregular rpm function, if the vehicle starts at all.
5. Long cranking time when starting cold
6. Engine may run rough on an intermittent basis, poor idle, poor acceleration, stumbling and/or hesitation.
7. Drop in mileage and stalling upon acceleration.

Throttle Position Sensor failure symptoms

1. A car that seems to hesitate or stumble during acceleration may have a faulty throttle position sensor.
2. If your car idles unevenly or hesitates intermittently, regardless of acceleration, the throttle position sensor may simply have a loose connection.

Oxygen Sensor failure symptoms

1. A sudden decrease in gas mileage.
2. Check engine light may illuminate.
3. Smog test failures can also be an indication of a failed oxygen sensor. EPA and CARB say 50 to 60% of all smog and emission tests related failures are attributed to the defective oxygen sensor. Faulty O2 sensor leads to either low or high CO emissions in the smog tests.
4. Engine may idle roughly, hesitate, or stumble. A bad oxygen sensor causes an engine's air/fuel mixture to become too lean. Normally, an air/fuel mixture that is too lean (too much air, not enough fuel) will cause an engine to miss, or misfire, especially when an engine is idling.

Knock Sensor failure symptoms

1. Check engine light may flash on your vehicle's dashboard.
2. If the knock sensor is not working properly, you will likely hear sounds emitting from the engine.
3. The vehicle will often shake or vibrate and misfire when the engine is started.
4. Stronger than normal exhaust and burning smells due to the detonation in the cylinders.
5. Fuel economy is often affected, causing the vehicle to burn more gas than usual and requiring frequent fuel replenishment.
6. May have acceleration problems, such as dragging, hesitation or jerking from the engine during speed increases.

Pick-Up Coil failure symptoms

1. A lack of spark because the spark plugs are not receiving the proper information to fire correctly.
2. The fuel injectors may fail to operate.
3. Rough idle may occur.
4. May cause engine stalling and an inability to accelerate smoothly.

Spark Plug Wires failure symptoms

1. Rough engine idle and/or misfire.
2. Engine hesitation, which is normally most apparent during acceleration.
3. Engine power loss and/or surging.

Ignition Switch failure symptoms

1. The dashboard lights will go off when the car stalls and the speedometer and tachometer (if you have one) will go off and come back on again.
2. Vehicle fails to start and stalls randomly while driving.
3. Switch gets overly hot.

Idle Air Control Valve failure symptoms

1. A faulty IAC will cause stalling problems at idle.
2. Most of the time if you hold the gas pedal down it will run fine. These symptoms can also come from an EGR valve that is stuck open.
3. If you have a fast idle, check for an intake leak.

Fuel Pump failure symptoms

1. Engine misfires causing the car to jump/buck occasionally while going along the highway. The fuel pump may act up for a mile or so two or three times and then run fine for the next 50 or more miles.
2. As you accelerate, the car starts to go and suddenly seems like it is going to die. Immediately, it seems to restart and off you go.
3. Power loss at highway speeds.
4. Will turn over, but will not start.

Timing Belt failure symptoms

1. No spark from the spark plugs.
2. Higher than normal amount of exhaust.
3. Difficult to start.
4. Engine may misfire, shake, hesitate, or stall if the timing is off.
5. Distributor rotor will not rotate.

Distributor/Cap/Rotor failure symptoms

1. Cylinder misfiring, engine shaking.
2. Trouble starting on a regular basis.
3. Starts okay but stalls and backfires once on the road.
4. High-pitched squealing noise.
5. A check engine light may be present.
6. If the distributor failed the vehicle will crank but not start.

Ignition Coil failure symptoms

1. A drop in power.
2. A total coil failure will cause a no spark, no run condition.
3. Decline in normal gas mileage.
4. May have black smoke out of the exhaust and smell of gasoline, rather than smelling like normal exhaust fumes.
5. May experience serious backfires, misfiring, and stalling.
6. Typically harder to start, especially when cold.

Ignition Control Module failure symptoms

1. High RPM misfire.
2. The car will start and run fine, but will stop running anywhere from seconds to minutes later. The engine may not restart immediately but if left to cool for about 10 minutes will start fine.
3. Hesitation/misfire under acceleration.
4. Failure to start.

Fuel Pressure Regulator failure symptoms

1. One or more of the spark plugs may have become fouled out and blackened.
2. When you are idling the engine it is not running smoothly and it is sputtering and spitting like it is going to die. If you haven't changed your fuel filter in a while, you should do that first and see if it helps. If not, then check the fuel pressure regulator.
3. Trouble starting the car. It will turn over but takes a few extra tries before it actually starts.
4. Tail pipe may have black smoke coming out of it.
5. Check the oil dipstick and see if you smell fuel on it.
6. Gasoline may be dripping out of the tailpipe.
7. The engine stalls when you press down on the gas pedal.

Fuel Filter failure symptoms

1. Engine may hesitate, stumble, or stall.
2. Rough engine idle.
3. Decrease in engine power.

Oil Pressure Switch failure symptoms

1. You might notice a leak from it, or a low oil pressure reading on the gauge.
2. The car will die out at times.

Vehicle Speed Sensor failure symptoms

1. The most common sign of a bad speed sensor is a speedometer or odometer that stops working. Also, you may not be able to set your vehicle to cruise control.
2. The following codes may be set: GM 24, Ford 27, 29, 452, Chrysler 28, 15
3. Typical OBD-II codes for a malfunctioning VSS are: P0500, P0501, P0502, P0503, P0716, P0718
4. May send out a wrong "too fast" signal, shutting down fuel flow at the wrong time.
5. Random or intermittent sudden loss of power and poor performance, only to have the engine resume normal operation.
6. Hesitation, roughness or sporadic jumps in your vehicle's transmission when you try to shift gears.
7. May rumble or idle irregularly when you start it, may burn more fuel than normal, may lose power suddenly due to wrong signals sent from the speed sensor to the fuel system.
8. Loss of anti-lock brakes, ABS warning lamps on the dash may be lit.
9. RPM limiter may be decreased.

Manifold Absolute Pressure Sensor failure symptoms

1. Engine will rev or surge suddenly, possibly causing the engine to sputter and die. May also surge while idling, such as at a stop light. You may also notice the engine idles rough when the car is on but not driving down the road.
2. The spark plugs may become fouled or coated with a white powdery substance.
3. Loss in engine power. Decreased fuel efficiency, consuming more gas than normal.
4. Check Engine Light may illuminate.
5. A rich or lean fuel mixture. May notice a gas smell even after warm-up and/or pinging at random times or all the time or whenever.
6. Rough idle and Hesitation.

TORQUE & HORSEPOWER

One of the most confusing (and frequently contentious) questions in the automotive realm is the difference between horsepower and torque. You may have heard any number of pithy expressions, like “horsepower sells cars, but torque wins races,” or fans of big-engine muscle cars complaining that 200-horsepower four-cylinder engines are “gutless.” Surprisingly few of the worthies who throw around comments like that, though, are actually able to define the difference. What IS the difference between horsepower and torque, and what effect do they have on how a car performs?

UNDERSTANDING TORQUE

If you stayed awake through high school physics, you may dimly recall that torque istwisting force — that is, a force that tries to cause an object to rotate around a particular axis. For example, if you turn a doorknob or spin a roulette wheel, you are applying torque to it.

If we were in physics class, we’d say that torque is the cross product of the vector of the force applied and the distance vector. The force vector is the direction in which you’re applying force. The distance vector is (at its simplest) the distance between the point where you’re applying the force and the axis of rotation. For example, imagine you are using a wrench to turn a bolt. In that case, the center of the bolt is the axis of rotation. If the wrench is one foot long and you apply ten pounds of force to the end of it, you are applying 10 pounds-feet of torque to the bolt. If the wrench was two feet long and you applied ten pounds of force at its end, you’d be applying 20 pounds-feet of torque.

What is engine torque? As you probably know, an internal combustion engine works by burning air and fuel. The energy of that combustion moves one or more pistons (or rotors), which act on the engine’s crankshaft, causing it to rotate. In a car, the rotation of the crankshaft turns the gears in the transmission, which turn the wheels. An engine’s torque is the amount of twisting force the pistons (or rotors) can exert on the crankshaft.

UNDERSTANDING HORSEPOWER

Now, what is horsepower? Again recalling that long-ago physics class, power is workperformed over time. Mechanical work represents force exerted over distance — for example, moving a 10-pound weight a distance of one foot represents 10 foot-pounds of work. Power is the rate at which that work is performed. One mechanical horsepowerrepresents the ability to do 550 foot-pounds of work per second, or 33,000 foot-pounds of work per minute. (One metric horsepower represents a rate of 75 kilogram-meters per second; a metric horsepower is about 735 watts, whereas a mechanical horsepower is equivalent to about 746 watts.)

The brighter students among us may have noticed the similarity between the units for work — foot-pounds (ft-lb) — and the units for torque — pounds-feet (lb-ft). In fact, the units are the same; the only reason they’re written differently is to avoid confusion. For an engine with a rotating crankshaft, then, one horsepower is equivalent to exerting 550 pounds-feet of torque per second.

Remember that torque is a twisting force; that means that if applying torque to an object will tend to cause the object to rotate, rather than move in a straight line. Therefore, if torque produces any work, we have to measure how much rotation it imparts (angular speed), rather than how far it cause the object to move. Angular speed is usually expressed in terms of radians per second or radians per minute (one radian is 180 degrees divided by π, or about 57.3 degrees), but since we usually measure engine speed in terms of revolutions per minute (rpm), it’s more useful to think of it that way. One revolution is 360 degrees, which is equal to 2π radians. If 1 horsepower equals 33,000 lb-ft of work per minute, then we can calculate an engine’s power based on its torque (in lb-ft) and its engine speed (in rpm):

Power (hp) = Torque (lb-ft) x 2π x Rotational Speed (rpm) / 33,000

or

Power (hp) = Torque (lb-ft) x Rotational Speed / 5,252.113

For example, if an engine produces 200 lb-ft of torque at 4,000 rpm, it has 152.3 horsepower (200 x 4,000 / 5,252.113) at that speed.

The upshot: Horsepower depends on torque and engine speed. If your engine produces more torque, it also makes more power; if you run the engine at a higher speed, it also makes more power. It is entirely possible for engine A to make more power than engine B, even if engine B makes more torque — engine A must simply rev higher to make up for its torque deficiency.

TORQUE AND POWER CURVES

Engines used for stationary applications (generators, for example) or in aircraft spend most of their lives running at a constant engine speed. As a result, they produce their full, rated horsepower most of the time. Engines used in cars, trucks, or motorcycles operate over a broad range of engine speeds, from a few hundred rpm at idle to 10,000 rpm or more at redline. Since horsepower depends in part on engine speed, the amount of power the engine produces varies quite a bit at different points in its rev range. Engineers describe the relationship between an engine’s power and rpm as the power curve.

If an engine produced its maximum torque at all engine speeds, the power curve would be a straight line: that is, increasing rpm by 50% would also increase horsepower by 50% (as long as it didn’t rev the engine beyond its redline, which risks serious mechanical failure). That is true of electric motors, but it isn’t true of internal combustion engines. We will discuss the reasons for this in more detail in a future article, but for now, we’ll just say that an engine’s torque output also varies with engine speed.

All internal combustion engines produce their maximum torque at one particular engine speed; this is called the torque peak. Above or below the torque peak, the engine produces somewhat less torque than that maximum value. Just as an engine has a power curve describing how much power the engine produces at different points in its rev range, the engine also has a torque curve, describing how much torque it generates at different speeds. The engine’s design determines at what speed the engine’s torque peak occurs, as well as the shape of the torque curve. If an engine produces a fairly constant level of torque throughout its rev range, its torque curve is said to be flat. Electric motors, which usually produce close to their full torque output from zero rpm all the way to their maximum safe operating speed, have extremely flat torque curves. (Contrary to popular belief, the shape of the torque curve is not directly related to how much torque the engine produces. Two engines can have very similarly shaped torque curves, even if one has far more maximum torque than the other does. Again, we will look more at the factors that determine the shape of the torque curve in a future installment.)

An engine can be tuned to produce its maximum torque at the low end of its rev range, in the mid-range, or at high rpm. Modern engine designers have various tricks available to “flatten” the torque curve of an engine (that is, to keep engine torque close to its maximum through a broad range of engine speeds), but any given engine will be notably stronger in one range than in others.

Since power is a function of torque and rpm, the shape of the torque curve also determines the shape of the power curve. The horsepower curve will always peak later than the torque curve, but if the engine’s torque curve is strongest at low rpm, the power peak will also be relatively low. If the torque peak is at high rpm, horsepower will also peak at lofty engine speeds.

If you’ve ever driven a car with a tachometer, you’ve probably noticed that the engine spends much of its time at speeds well under 4,000 rpm. Since the horsepower peak of almost every modern engine is higher than 4,000 rpm, that means the engine rarely has a chance to develop its rated maximum power. Therefore, in normal driving, the shape of the torque curve is often more important than maximum power.

THE REAL WORLD (SORT OF)

To see how this works in practice, let’s consider a couple of real engines: Ford’s 4.0 L “Cologne” V6 (which powered the Ford Ranger and Explorer for many years) and Volkswagen’s turbocharged, four-cylinder 1.8T engine (used in several different configurations in a wide range of Volkswagen and Audi models).

The Ford Cologne V6 was an engine of venerable design dating back to the early 1960s. The 4.0 L (245 cu. in.) version was intended for truck use, so it was tuned for strong low-end torque. Its peak torque was 220 lb-ft at only 2,400 rpm; maximum horsepower was 160 at a modest 4,200 rpm.

Volkswagen’s 1.8T was a more modern and far more technically sophisticated engine with dual overhead camshafts, five valves per cylinder, and an intercooled turbocharger.Turbocharged engines tend to be “peaky,” putting out more power at high rpm, but Volkswagen designed it to have as flat a torque curve as possible. In fact, Volkswagen claimed that the engine produced its full maximum torque from 1,950 rpm to 5,000 rpm. VW offered it in several states of tune, but the one we’ll use for our discussion is the version found in later Mk 4 Golfs, Jetta/Bora sedans, and the SEAT León, which had 180 horsepower @ 5,500 rpm and 173 lb-ft of torque.

The best way to judge an engine’s torque curve is to hook it up to a dynamometer and see exactly how much torque it actually puts out at various rpm. We aren’t in a position to do that, but we can make some educated guesses about the torque curves for both engines based on their rated torque and horsepower peaks.

As we mentioned above, the Ford engine’s rated torque peak is at 2,400 rpm. Using the equation we derived earlier, we can calculate its power output at that speed: 101 horsepower (220 lb-ft x 2,400 rpm / 5,252). The V6′s horsepower peak comes at 4,200 rpm. Using the same equation, we calculate that it has 200 lb-ft of torque at that speed (160 hp x 5,252 / 4,200 rpm). We can see from those numbers that between 2,400 and 4,200 rpm, the engine probably produces between 200 and 220 lb-ft of torque.

What about at higher speeds? We know that the engine never produces more than 160 horsepower. Even if it still produced 160 horsepower at 5,000 rpm (which is unlikely), torque would have dropped to 168 lb-ft at that speed. If it produced 140 horsepower at 5,000 rpm, that would mean that its torque output was down to 147 lb-ft. In short, the Ford engine’s torque and power both start dropping off very rapidly after the 4,200-rpm horsepower peak — the V6 was designed for low-end grunt, not high-rpm power.

What about the Volkswagen engine? The 1.8T’s peak torque begins at 1,950 rpm. At that speed, it’s making only 64 hp (173 lb-ft x 1,950 rpm / 5,252). By 2,400 rpm (the Ford’s torque peak), the VW engine’s horsepower has risen to 79. At 4,200 rpm, the 1.8T has risen to 138 hp, still well behind the Ford. The VW’s power doesn’t start to exceed that of the Ford engine until after the Ford hits its peak power. When the VW hits its peak horsepower at 5,500 rpm, torque is still about 172 lb-ft — torque has tapered off, but only very slightly. That means the engine continues to make useful power even past its power peak; its redline is 6,500 rpm, which it doesn’t have much trouble reaching.

These torque and horsepower curves are estimates based on published power and torque figures, but they illustrate the difference between the engines. Note that even though the VW’s torque curve (light green) is far flatter than the Ford’s, the Ford’s is higher over much of the rev range.

What does this mean in practical terms? Even though the VW’s torque curve is very flat, it has significantly less torque than the Ford until well over 4,200 rpm, which means that the 1.8T also has less power at lower speeds. It ultimately produces more power than the Ford engine, but not until over 5,000 rpm.

Imagine that we installed these engines in two otherwise identical cars, with the same transmissions, same gearing, and identical weight. We would discover the following:

• In normal, street driving, the car with the Ford engine would almost always be quicker than the VW-powered car. That shouldn’t be surprising — the Ford’s greater torque gives it almost 30% more power than the VW engine at low rpm, even if the VW is stronger at higher speeds.
• In a drag race over a standing quarter mile or standing kilometer, the Ford-powered car would take an early lead and would stay ahead until both cars were well down the strip. The 1.8T car would begin to catch up as it hit higher engine speeds and it would eventually pull ahead. It would win by a narrow margin and its trap speed (its speed at the finish line) would be slightly higher than the Ford-powered car’s.
• In a road race or on a big NASCAR-style oval track, the VW-powered car would be ahead most of the time. As long as both cars were driven flat out, the VW engine’s greater horsepower would be more important than the Ford’s low-speed torque. The only place the Ford-powered car would have an advantage would be in slow corners, where its higher torque would again give it more power than the VW engine.

This assumes everything else is equal, which in the real world isn’t necessarily the case. For example, we could help the VW-engined car by changing its gear ratios so that the engine is always running at higher rpm. This would give it more power in low-speed driving, although it would also mean more engine noise, greater fuel consumption, and somewhat higher engine wear.

Hero Honda New Karizma ZMR Review

Hero Honda Karizma became extremely popular following its launch in the Indian bike market. The company then launched the Hero Honda Karizma ZMR Fi. The new bike has a similar stance and the changes include programmed fuel injection feature incorporated in this bike. The bike is also more powerful and has a new rear disc brake.

Hero Honda New Karizma ZMR Specifications

The Hero Honda New Karizma ZMR review indicates that the bike has a 223cc engine which is the same as the old version bike. However the fuel injection feature provides increase in power and the bike has maximum power of 17.6 bhp at 7000 rpm along with peak torque of 18.35 Nm at 6000 rpm. The bike has 5-speed gears and multiplate wet clutch.

The bike has length of 2110mm and its width is 805mm while its height is 1175mm. The top speed of the bike is 126 km/hr and it can reach 0 to 60 km/hr in just 3.7 seconds. The PGM-Fi feature has sensors that measure aspects like air temperature, air pressure as well as engine temperature so as to identify ideal air and fuel ratio.

The Hero Honda New Karizma ZMR review also indicates that the bike has telescopic hydraulic front shock absorbers and 5-step adjustable iGRS system for the rear. The bike also has 276mm disc brake for the front and 240mm disc rear brakes. The weight of the bike is 159 kgs along with ground clearance of 159mm. The fuel tank limit of the bike is 16 litres and it has a wheelbase of 1350mm.

Hero Honda New Karizma ZMR Mileage

The bike can deliver mileage of around 40 to 50 km/litre

Hero Honda New Karizma ZMR Features

The front design of the bike is similar to the old Karizma and the bike has plenty of snazzy graphics. The bike also gets several new features and these include integrated blinkers and new headlamps. The finish of the bike and paint quality is also excellent. The bike has a beautifully designed instrument cluster and the rider is greeted with a long message when the key is inserted and the bike is started. The display of the bike also shows fuel consumption in real time and this helps in ensuring that good mileage in maintained. The other aspects displayed include digital fuel gauge and speedometer.

Hero Honda New Karizma ZMR Price and design variations

The starting price of the bike is around Rs 1.02 lakhs and the bike is available in a single design variation.

Hero Honda New Karizma ZMR Colors

The bike is available in five colors and these include pearl white, vibrant blue, sports red, panther black and moon yellow.

Motorbike Run in Period Tips ...

1. Ride smooth and Do not allow the Speedo to cross 40kmph for the first 2000km (however boring it may be!).
2. Take one or two long rides of say 100/150km or more, involving a few high gradients.
3. Always drive in the appropriate Gear so as not to strain the engine.
4. Shift Gears smoothly and accelerate in moderation (not sharp & sudden).
5. Do not disturb Carburettor setting (by setting for a lean mixture) even if you don’t get the expected mileage at this stage of the bike’s life.
6. DO NOT ever lend the bike to any one else during the running-in-period. Tell gently & excuse yourself. If unavoidable, drive yourself taking him pillion.
7. Avoid pillion riding to the extent possible.
8. Get serviced immediately on running 500km & 2000km.
9. After 2nd servicing (2000km), you can gradually start accelerating to higher speeds which could be, say 50…55…60…. and so on, after every 75/100km.
10. It’s fine if your mechanic is good, but better you learn how to do appropriate carburettor setting yourself, which you can master by trail and error. (You may please refer to the article on this aspect in bikeadvice.in).
11. This, you may resort to, in case you are not happy with the bike’s fuel efficiency, and only after the 2nd service.
12. Understand your bike and love it for what it is!
13. Don’t bother to compare it with others, since each bike is built to meet and deliver a certain of your expectations and definitely not all the best under the Sun!
14. Treat the new bike like a bride during the running-in period, and you sure will have a real good partner in the years ahead!
15. As far as possible, fill fuel of uniform quantity (and always check air pressure within a week -25/35-front/rear-for your Jive) at a selected bunk known for good quality petrol. Do not go for higher octane fuel, it’s not advisable.
16. Remember, with proper care & timely maintenance, any Bike of whichever Make would rerurn good mileage and serve you for long.
17. Even the best of a bike in wrong hands will flop within no time.