Percentage of energy generated by the fuel to move your car<?xml:namespace prefix = o ns = "urn:schemas-microsoft-com:office:office" /><o:p></o:p>
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An IT guy asked me today, “Do you know how many % of energy that generated by the fuel delivers to a car’s wheels and moves the car, and how many % is wasted actually?†<o:p></o:p>
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Shame on me that been into cars for so many years and I still couldn’t answer him on the spot. (seriously i feel like killing myself that moment)
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"The answer is about 20% only; the rest of the 80% is lostâ€, he said. And i can't believe it when I found this information online. <o:p></o:p>
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The diagram below shows typical energy uses and losses in a vehicle.<o:p></o:p>
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[media]http://i292.photobucket.com/albums/mm29/trialspirit/untitled-1.jpg[/media]
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Only about 15% of the energy from the fuel you put in your tank gets to move your car down the road or run useful accessories, such as air conditioning. The rest of the energy is lost to engine and driveline inefficiencies and idling. Therefore, the potential to improve fuel efficiency with advanced technologies is enormous.
So It’s, <o:p></o:p>
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100% - 17.2% standby/idle - 2.2% accessories - 62.4% engine losses = 18.2% - 5.6% driveline looses = 12.6%
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Engine Losses – 62.4%<o:p></o:p>
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In gasoline-powered vehicles, over 62% of the fuel's energy is lost in the internal combustion engine (ICE). ICE engines are very inefficient at converting the fuel's chemical energy to mechanical energy, losing energy to engine friction, pumping air into and out of the engine, and wasted heat. <o:p></o:p>
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Advanced engine technologies such as variable valve timing and lift, turbocharging, direct fuel injection, and cylinder deactivation can be used to reduce these losses.<o:p></o:p>
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In addition, diesels are about 30-35% more efficient than gasoline engines, and new advances in diesel technologies and fuels are making these vehicles more attractive.<o:p></o:p>
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Idling Losses – 17.2%<o:p></o:p>
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In urban driving, significant energy is lost to idling at stop lights or in traffic. Technologies such as integrated starter/generator (ISG) systems help reduce these losses by automatically turning the engine off when the vehicle comes to a stop and restarting it instantaneously when the accelerator is pressed. <o:p></o:p>
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Accessories – 2.2%<o:p></o:p>
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Air conditioning, power steering, windshield wipers, and other accessories use energy generated from the engine. Fuel economy improvements of up to 1% may be achievable with more efficient alternator systems and power steering pumps.<o:p></o:p>
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Driveline Losses – 5.6%<o:p></o:p>
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[FONT=宋体]Energy is lost in the transmission and other parts of the driveline. Technologies, such as automated manual transmission (AMT) and continuously variable transmission (CVT), are being developed to reduce these losses. <o:p></o:p>[/FONT]
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Rolling Resistance – 4.2%<o:p></o:p>
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Rolling resistance is a measure of the force necessary to move the tire forward and is directly proportional to the weight of the load supported by the tire. A variety of new technologies can be used to reduce rolling resistance, including improved tire tread and shoulder designs and materials used in the tire belt and traction surfaces.<o:p></o:p>
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For passenger cars, a 5-7% reduction in rolling resistance increases fuel efficiency by 1%. However, these improvements must be balanced against traction, durabillity, and noise.<o:p></o:p>
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Aerodynamic Drag – 2.6%<o:p></o:p>
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A vehicle must expend energy to move air out of the way as it goes down the road—less energy at lower speeds and progressively more as speed increases. Drag is directly related to the vehicle's shape. Smoother vehicle shapes have already reduced drag significantly, but further reductions of 20-30% are possible.<o:p></o:p>
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Overcoming Inertia; Braking Losses– 5.8%<o:p></o:p>
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To move forward, a vehicle's drivetrain must provide enough energy to overcome the vehicle's inertia, which is directly related to its weight. The less a vehicle weighs, the less energy it takes to move it. Weight can be reduced by using lightweight materials and lighter-weight technologies (e.g., automated manual transmissions weigh less than conventional automatics).<o:p></o:p>
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In addition, any time you use your brakes, energy initially used to overcome inertia is lost.
<o:p></o:p>
<o:p></o:p>
An IT guy asked me today, “Do you know how many % of energy that generated by the fuel delivers to a car’s wheels and moves the car, and how many % is wasted actually?†<o:p></o:p>
<o:p></o:p>
Shame on me that been into cars for so many years and I still couldn’t answer him on the spot. (seriously i feel like killing myself that moment)
<o:p></o:p>
"The answer is about 20% only; the rest of the 80% is lostâ€, he said. And i can't believe it when I found this information online. <o:p></o:p>
<o:p></o:p>
<o:p></o:p>
<o:p></o:p>
<o:p></o:p>
The diagram below shows typical energy uses and losses in a vehicle.<o:p></o:p>
<o:p></o:p>
<o:p></o:p>
<o:p></o:p>
[media]http://i292.photobucket.com/albums/mm29/trialspirit/untitled-1.jpg[/media]
<o:p></o:p>
<o:p></o:p>
<o:p></o:p>
Only about 15% of the energy from the fuel you put in your tank gets to move your car down the road or run useful accessories, such as air conditioning. The rest of the energy is lost to engine and driveline inefficiencies and idling. Therefore, the potential to improve fuel efficiency with advanced technologies is enormous.
So It’s, <o:p></o:p>
<o:p></o:p>
100% - 17.2% standby/idle - 2.2% accessories - 62.4% engine losses = 18.2% - 5.6% driveline looses = 12.6%
<o:p></o:p>
Engine Losses – 62.4%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
In gasoline-powered vehicles, over 62% of the fuel's energy is lost in the internal combustion engine (ICE). ICE engines are very inefficient at converting the fuel's chemical energy to mechanical energy, losing energy to engine friction, pumping air into and out of the engine, and wasted heat. <o:p></o:p>
<o:p></o:p>
Advanced engine technologies such as variable valve timing and lift, turbocharging, direct fuel injection, and cylinder deactivation can be used to reduce these losses.<o:p></o:p>
<o:p></o:p>
In addition, diesels are about 30-35% more efficient than gasoline engines, and new advances in diesel technologies and fuels are making these vehicles more attractive.<o:p></o:p>
<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
Idling Losses – 17.2%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
In urban driving, significant energy is lost to idling at stop lights or in traffic. Technologies such as integrated starter/generator (ISG) systems help reduce these losses by automatically turning the engine off when the vehicle comes to a stop and restarting it instantaneously when the accelerator is pressed. <o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
Accessories – 2.2%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
Air conditioning, power steering, windshield wipers, and other accessories use energy generated from the engine. Fuel economy improvements of up to 1% may be achievable with more efficient alternator systems and power steering pumps.<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
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Driveline Losses – 5.6%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]Energy is lost in the transmission and other parts of the driveline. Technologies, such as automated manual transmission (AMT) and continuously variable transmission (CVT), are being developed to reduce these losses. <o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
Rolling Resistance – 4.2%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
Rolling resistance is a measure of the force necessary to move the tire forward and is directly proportional to the weight of the load supported by the tire. A variety of new technologies can be used to reduce rolling resistance, including improved tire tread and shoulder designs and materials used in the tire belt and traction surfaces.<o:p></o:p>
<o:p></o:p>
For passenger cars, a 5-7% reduction in rolling resistance increases fuel efficiency by 1%. However, these improvements must be balanced against traction, durabillity, and noise.<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
Aerodynamic Drag – 2.6%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
A vehicle must expend energy to move air out of the way as it goes down the road—less energy at lower speeds and progressively more as speed increases. Drag is directly related to the vehicle's shape. Smoother vehicle shapes have already reduced drag significantly, but further reductions of 20-30% are possible.<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
[FONT=宋体]<o:p></o:p>[/FONT]
Overcoming Inertia; Braking Losses– 5.8%<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
To move forward, a vehicle's drivetrain must provide enough energy to overcome the vehicle's inertia, which is directly related to its weight. The less a vehicle weighs, the less energy it takes to move it. Weight can be reduced by using lightweight materials and lighter-weight technologies (e.g., automated manual transmissions weigh less than conventional automatics).<o:p></o:p>
[FONT=宋体]<o:p></o:p>[/FONT]
In addition, any time you use your brakes, energy initially used to overcome inertia is lost.
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