Energy-efficient driving techniques are used by drivers who wish to reduce their fuel consumption.
Simple fuel efficiency techniques can result in a reduction in fuel consumption without resorting to radical fuel-saving techniques that can be unlawful and dangerous, such as tailgating larger vehicles.
- 1 Techniques
- 1.1 Maintenance
- 1.2 Mass and improving aerodynamics
- 1.3 Maintaining an efficient speed
- 1.4 Choice of gear (manual transmissions)
- 1.5 Acceleration and deceleration (braking)
- 1.6 Coasting or gliding
- 1.7 Anticipating traffic
- 1.8 Minimizing ancillary losses
- 1.9 Fuel type
- 1.10 Pulse and glide
- 1.11 Causes of pulse-and-glide energy saving
- 1.12 Drafting
- 1.13 Energy losses
- 1.14 Safety
- 2 See also
- 3 References
- 4 External links
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Underinflated tires wear out faster and lose energy to rolling resistance because of tire deformation. The loss for a car is approximately 1.0% for every 2 psi (0.1 bar; 10 kPa) drop in pressure of all four tires. Wheel alignment, fuel evaporation while parked, and high engine oil kinematic viscosity, all reduce fuel efficiency.
Mass and improving aerodynamics
Drivers can also increase fuel efficiency by minimizing transported mass, i.e. the number of people or the amount of cargo, tools, and equipment carried in the vehicle. Removing common unnecessary accessories such as roof racks, brush guards, wind deflectors (or "spoilers", when designed for downforce and not enhanced flow separation), running boards, push bars, and narrow and lower profile tires will improve fuel efficiency by reducing both weight and aerodynamic drag. Some cars also use a half size spare tire, for weight/cost/space saving purposes. On a typical vehicle, every extra 100 pounds increases fuel consumption by 2%. Removing roof racks (and accessories) can decrease fuel consumption by up to 20%.
Maintaining an efficient speed
Maintaining an efficient speed is an important factor in fuel efficiency. Optimal efficiency can be expected while cruising at a steady speed, at minimal throttle and with the transmission in the highest gear (see Choice of gear, below). The optimum speed varies with the type of vehicle, although it is usually reported to be between 35 mph (56 km/h) and 50 mph (80 km/h). For instance a 2004 Chevrolet Impala had an optimum at 42 mph (70 km/h), and was within 15% of that from 29 to 57 mph (45 to 95 km/h). At higher speeds wind resistance plays an increasing role in reducing energy efficiency.
Hybrids typically get their best fuel efficiency below this model-dependent threshold speed. The car will automatically switch between either battery powered mode or engine power with battery recharge. Electric cars such as the Tesla Model S may go up to 728.7 kilometres (452.8 mi) at 39 km/h (24 mph.) 
Road capacity affects speed and therefore fuel efficiency as well. Studies have shown speeds just above 45 mph (72 km/h) allow greatest throughput when roads are congested. Individual drivers can improve their fuel efficiency and that of others by avoiding roads and times where traffic slows to below 45 mph (72 km/h). Communities can improve fuel efficiency by adopting speed limits or policies to prevent or discourage drivers from entering traffic that is approaching the point where speeds are slowed below 45 mph (72 km/h). Congestion pricing is based on this principle; it raises the price of road access at times of higher usage, to prevent cars from entering traffic and lowering speeds below efficient levels.
Research has shown that mandated speed limits can be modified to improve energy efficiency anywhere from 2% to 18%, depending on compliance with lower speed limits.
Choice of gear (manual transmissions)
Engine efficiency varies with speed and torque. For driving at a steady speed one cannot choose any operating point for the engine—rather there is a specific amount of power needed to maintain the chosen speed. A manual transmission lets the driver choose between several points along the powerband. For a turbo diesel too low a gear will move the engine into a high-rpm, low-torque region in which the efficiency drops off rapidly, and thus best efficiency is achieved near the higher gear. In a gasoline engine, efficiency typically drops off more rapidly than in a diesel because of throttling losses. Because cruising at an efficient speed uses much less than the maximum power of the engine, the optimum operating point for cruising at low power is typically at very low engine speed, around or below 1000 rpm. This explains the usefulness of very high "overdrive" gears for highway cruising. For instance, a small car might need only 10–15 horsepower (7.5–11.2 kW) to cruise at 60 mph (97 km/h). It is likely to be geared for 2500 rpm or so at that speed, yet for maximum efficiency the engine should be running at about 1000 rpm to generate that power as efficiently as possible for that engine (although the actual figures will vary by engine and vehicle).
Acceleration and deceleration (braking)
Fuel efficiency varies with the vehicle. Fuel efficiency during acceleration generally improves as RPM increases until a point somewhere near peak torque (brake specific fuel consumption). However, accelerating to a greater than necessary speed without paying attention to what is ahead may require braking and then after that, additional acceleration. Experts recommend accelerating quickly, but smoothly.
Generally, fuel efficiency is maximized when acceleration and braking are minimized. So a fuel-efficient strategy is to anticipate what is happening ahead, and drive in such a way so as to minimize acceleration and braking, and maximize coasting time.
The need to brake is sometimes caused by unpredictable events. At higher speeds, there is less time to allow vehicles to slow down by coasting. Kinetic energy is higher, so more energy is lost in braking. At medium speeds, the driver has more time to choose whether to accelerate, coast or decelerate in order to maximize overall fuel efficiency.
While approaching a red signal, drivers may choose to "time a traffic light" by easing off the throttle before the signal. By allowing their vehicle to slow down early and coast, they will give time for the light to turn green before they arrive, preventing energy loss from having to stop.
When possible, avoid driving during rush hours as the stop and go driving is fuel inefficient and produces more toxic fumes.
Conventional brakes dissipate kinetic energy as heat, which is irrecoverable. Regenerative braking, used by hybrid/electric vehicles, recovers some of the kinetic energy, but some energy is lost in the conversion, and the braking power is limited by the battery's maximum charge rate and efficiency.
Coasting or gliding
An alternative to acceleration or braking is coasting, i.e. gliding along without propulsion. Coasting dissipates stored energy (kinetic energy and gravitational potential energy) against aerodynamic drag and rolling resistance which must always be overcome by the vehicle during travel. If coasting uphill, stored energy is also expended by grade resistance, but this energy is not dissipated since it becomes stored as gravitational potential energy which might be used later on. Using stored energy (via coasting) for these purposes is more efficient than dissipating it in friction braking.
When coasting with the engine running and manual transmission in neutral, or clutch depressed, there will still be some fuel consumption due to the engine needing to maintain idle engine speed.
Coasting with a vehicle not in gear is prohibited by law in most U.S. states. An example is Maine Revised Statutes Title 29-A, Chapter 19, §2064 "An operator, when traveling on a downgrade, may not coast with the gears of the vehicle in neutral". Some regulations differ between commercial vehicles not to disengage the clutch for downgrade, and passenger vehicles to set the transmission to neutral. This regulations point on how drivers operate a vehicle. Not using the engine on longer precipitous downgrade roads or permanent using the brake might cause a failure due overheating brakes.
Turning the engine off instead of idling does save fuel. Traffic lights are in most cases predictable, and it is often possible to anticipate when a light will turn green. A support is the Start-stop system, tuning the engine off and on automatically during a stop. Some traffic lights (in Europe and Asia) have timers on them, which assist the driver in using this tactic.
Some hybrids must keep the engine running whenever the vehicle is in motion and the transmission engaged, although they still have an auto-stop feature which engages when the vehicle stops, avoiding waste. Maximizing use of auto-stop on these vehicles is critical because idling causes a severe drop in instantaneous fuel-mileage efficiency to zero miles per gallon, and this lowers the average (or accumulated) fuel-mileage efficiency.
A driver may improve their fuel efficiency by anticipating the movement of other vehicles. For example, a driver who stops quickly, or turns without signaling, reduces the options another driver has for maximizing their performance. By always giving road users as much information about their intentions as possible, a driver can help other road users reduce their fuel usage (as well as increase their safety). Similarly, anticipation of road features such as traffic lights can reduce the need for excessive braking and acceleration.
Minimizing ancillary losses
Using air conditioning requires the generation of up to 5 hp (3.7 kW) of extra power to maintain a given speed. A/C systems cycle on and off, or vary their output, as required by the occupants so they rarely run at full power continuously. Rolling down the windows is often seen as the leading way to prevent this loss of energy. This technique, however, causes increased drag in the form of air resistance and the cost savings is less than is generally anticipated. Using the passenger heating system slows the rise to operating temperature for the engine. Either the choke in a carburetor-equipped car (1970's or earlier) or the fuel injection computer in modern vehicles will add more fuel to the fuel-air mixture until normal operating temperature is reached, decreasing fuel efficiency.
Using high octane gasoline fuel in a vehicle that does not need it is generally considered an unnecessary expense, although Toyota has measured slight differences in efficiency due to octane number even when knock is not an issue. All vehicles in the United States built since 1996 are equipped with OBD-II on-board diagnostics and most models will have knock sensors that will automatically adjust the timing if and when pinging is detected, so low octane fuel can be used in an engine designed for high octane, with some reduction in efficiency and performance. If the engine is designed for high octane then higher octane fuel will result in higher efficiency and performance under certain load and mixture conditions. The energy released during combustion of hydrocarbon fuel increases as the molecule chain length decreases, so gasoline fuels with higher ratios of the shorter chain alkanes such as heptane, hexane, pentane, etc. can be used under certain load conditions and combustion chamber geometries to increase engine output which can lead to lower fuel consumption, although these fuels will be more susceptible to predetonation ping in high compression ratio engines. Gasoline direct injection compression ignition engines make more efficient use of the higher combustion energy short chain hydrocarbons as the fuel is injected directly into the combustion chamber during high compression which auto-ignites the fuel, minimizing the amount of time that the fuel is available in the combustion chamber for predetonation.
Pulse and glide
Pulse and glide (PnG) or burn and coast driving strategy consists of rapid acceleration to a given speed (the "pulse" or "burn"), followed by a period of coasting or gliding down to a lower speed, at which point the burn-coast sequence is repeated. Coasting is most efficient when the engine is not running, although some gains can be realized with the engine on (to maintain power to brakes, steering and ancillaries) and the vehicle in neutral. Most modern petrol vehicles cut off the fuel supply completely when coasting (over-running) in gear, although the moving engine adds considerable frictional drag and speed is lost more quickly than with the engine declutched from the drivetrain.
The pulse-and-glide strategy is proven to be an efficient control design both in car-following and free-driving scenarios, with 20% fuel saving. In the PnG strategy, the control of the engine and the transmission determines the fuel-saving performance, and it is obtained by solving an optimal control problem (OCP). Due to a discrete gear ratio, strong nonlinear engine fuel characteristics, and different dynamics in the pulse/glide mode, the OCP is a switching nonlinear mixed-integer problem.
Some hybrid vehicles are well-suited to performing pulse and glide. In a series-parallel hybrid (see hybrid vehicle drivetrain), the internal combustion engine and charging system can be shut off for the glide by simply manipulating the accelerator. However based on simulation, more gains in economy are obtained in non-hybrid vehicles.
This control strategy can also be used in vehicle platoon (The platooning of automated vehicles has the potential of significantly enhancing the fuel efficiency of road transportation), and this control method performs much better than conventional linear quadratic controllers.
Pulse and glide ratio of combustion engine in hybrid vehicles points on it by gear ratio in its consumption map, battery capacity, battery level, load, depending on acceleration, wind drag and its factor of speed.
Causes of pulse-and-glide energy saving
Much of the time, automobile engines operate at only a fraction of their maximal efficiency, resulting in lower fuel efficiency (or what is the same thing, higher specific fuel consumption (SFC)). Charts that show the SFC for every feasible combination of torque (or Brake Mean Effective Pressure) and RPM are called Brake specific fuel consumption maps. Using such a map, one can find the efficiency of the engine at various combinations of rpm, torque, etc.
During the pulse (acceleration) phase of pulse and glide, the efficiency is near maximal due to the high torque and much of this energy is stored as kinetic energy of the moving vehicle. This efficiently-obtained kinetic energy is then used in the glide phase to overcome rolling resistance and aerodynamic drag. In other words, going between periods of very efficient acceleration and gliding gives an overall efficiency that is usually significantly higher than just cruising at a constant speed. Computer calculations have predicted that in rare cases (at low speeds where the torque required for cruising at steady speed is low) it's possible to double (or even triple) fuel economy. More realistic simulations that account for other traffic suggest improvements of 20% are more likely. In other words, in the real world one is unlikely to see fuel efficiency double or triple. Such a failure is due to signals, stop signs, and considerations for other traffic; all of these factors interfering with the pulse and glide technique. But improvements in fuel economy of 20% or so are still feasible.
Drafting occurs where a smaller vehicle drives (or coasts) close behind a vehicle ahead of it so that it is shielded from wind. Aside from being illegal in many jurisdictions it is often dangerous. Scale-model wind tunnel and Real-World tests of a car ten feet behind a semi-truck showed a reduction of over 90% for the wind force (aerodynamic drag). The gain in efficiency is reported to be 20–40%.
Most of the fuel energy loss in cars occurs in the thermodynamic losses of the engine. The next biggest loss is from idling, or when the engine is in standby, which explains the large gains available from shutting off the engine.
In this respect, the data for fuel energy wasted in braking, rolling resistance, and aerodynamic drag are all somewhat misleading, because they do not reflect all the energy that was wasted up to that point in the process of delivering energy to the wheels. The image reports that on non-highway (urban) driving, 6% of the fuel's energy is dissipated in braking; however, by dividing this figure by the energy that actually reaches the axle (13%), one can find that 46% of the energy reaching the axle goes to the brakes. Also, additional energy can potentially be recovered when going down hills, which may not be reflected in these figures.
There is sometimes a tradeoff between saving fuel and preventing crashes.
In the US, the speed at which fuel efficiency is maximized often lies below the speed limit, typically 35 to 50 mph (56 to 80 km/h); however traffic flow is often faster than this. The speed differential between cars raises the risk of collision.
Drafting increases risk of collision when there is a separation of fewer than three seconds from the preceding vehicle.
Coasting is another technique for increasing fuel efficiency. Shifting gears and/or restarting the engine increase the time required for an avoidance maneuver that requires acceleration. Therefore, some believe the reduction of control associated with coasting is an unacceptable risk.
- Alternative fuel vehicle
- Fuel economy in automobiles
- Fuel efficiency
- Fuel saving device
- Plug-in hybrid
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