Honda FCX

Honda Motor Co. has finally unveiled its next-generation hydrogen fuel cell vehicle last Thursday with the announcement that it would begin producing a small number of vehicles that will be marketed in Japan and United States.

The new Honda FCX is made more sporty and sleeker as compared to the current version that has a top speed of 100 mph. It also has a longer range from 210 miles to 270 miles and of course a fuel cell power system that is 400 pounds lighter. Its auto parts such as air induction and others were also modified to function on hydrogen fuel.

The introduction of the FCX was right on timing since there is a growing concern for the greenhouse gas emissions not to mention the calls in Congress to dramatically raise fuel economy standards to minimize exhaust emissions.

Hydrogen vehicles provide lower net carbon dioxide emissions. Plus it can help end US dependency on foreign oil. Sadly this is easier said than done. The expenses that comes with building hydrogen fuel cells not to mention the absence of hydrogen fueling stations around the country creates a major obstruction for the fulfillment of this goal.

But thanks to companies like Honda which is at present is looking at an experimental home energy station that is making use of natural gas supplied to most homes to produce hydrogen fuel, hot water, heat, and electricity. According to Ben Knight, Honda’s vice president for research in the Americas, the best thing about hydrogen is that it can be extracted from a broad range of sources that includes methane or natural gas, bio-mass and renewable sources like solar or wind.

He further added that the next generation FCX is a “quantum leap forward”. The FCX will also be given a much higher price tag at least $500 more totaling to only a fraction of the approximate $1.5 million production cost of each Hydrogen fuel celled Honda.

Honda has already sold 30 units of their eco-friendly car worldwide. Mr. Knight also said that the production of the FCX model would eventually surpass the current fleet. Just to give customers a taste of what the FCX has to offer Honda has leased one to a family in California two years ago and last March another FCX was leased to a 17-year-old actress and environmental activist Q'orianka Kilcher. Honda has also allowed journalists to test drive two of its FCX. In addition government officials including top White House environmental adviser James COnnaughton were also invited to test drive Honda’s FCX.

The FCX when accelerating gives off a sound similar to a jet engine rather than a conventional gasoline engine. It is also has superior acceleration as compared to the current model that has a top speed of only 100 mph. Honda has also assured that the production vehicle will be similar to the concept showed last Thursday complete with the upgraded bumpers and revised interior.

Honda is not the only automaker that is conducting research on hydrogen vehicles; most major carmakers have spent billions on research alone. China is also investing heavily in hydrogen and if everything goes well for them they may even become the first country to adopt hydrogen vehicles in large volume.

It can be remembered that General Motors has said that it would introduce the world’s largest fleet of hydrogen-powered Chevrolte Equinox SUVs by means of its “Project Driveway” program in New York, Washington, DC, and California. And next week GM has scheduled a tour to take journalists on a 300-mile drive from its labs in Honeoye Falls, N.Y. to Tarrytown, N.Y., to update them on the progress of its hydrogen research. GM is hoping to build a 1000 vehicle fleet between 2010 and 2012.

Ford Motor Co. is also working on its plug-in electric hydrogen-powered vehicle with a range of 225 miles which will be called HySEries Edge. In addition Ford will have a fleet of hydrogen powered E-450 shuttle buses aside from hydrogen vehicles. DaimlerChrysler for its part will also be producing 100 hydrogen fuel cells to be distributed worldwide and that includes the 25 units destined for California. BMW will also be producing its own 100 Hydrogen 7 vehicles and plans to be leasing them next year.

Toyota Prius Review

Concept vehicles are big in the world of cars. The Toyota Prius has the distinction of being the worlds cleanest and planet friendly vehicle. It has been given the honor of being the 2006 European Car of the year because of the standards that it set for manufactures when building their hybrid cars. Consumer Reports even reported that the Toyota Prius came in with a 94 percent owner satisfaction rating. Most of the current owners of a Prius would definitely purchase another one again, thus making Consumer Reports rate it as the most satisfying vehicles on the road.

So Just what make the Prius a step above the rest? The Toyota Prius is an astonishing Hybrid. The way Toyota uses technology is quite amazing. Instead of just turning a key to start the ignition, the Toyota Prius is started by pressing a round ?Power? button on the dash board. Toyota has incorporated an interactive touch sensitive multi-informational display screen that is mounted on the center console. This display screen has many functions from showing you fuel consumption, radio settings, climate control, and many other functions that are occurring within the vehicle.

The Toyota Prius carries a rating of Advanced Technology Partial Zero Emission Vehicle, making it the cleanest emission production car on the road today. The Prius boasts an average of 90 percent more cleaner air than the average car on the road today. It employs the Hybrid Synergy Drive technology making it the leading vehicle in the industry of Hybrid technology. It offers a seamless integration of gas engine and emissions free electric motor allowing it to achieve amazing fuel economy. This makes it the best choice for the environment and the consumer.

Hybrids have become more and more popular in the world because of its dramatically increased fuel efficiency; especially with the rising cost of gas prices all over the world. People tend to flock to cars that will give them the most bang for their buck and are environmentally friendly. This make the Toyota Prius the most environmentally friendly care on the road today and thus, will be a good choice for you, your family, and the environment.

Ethanol in the Race of the Bio-Fuels

Much talk has been going on about the use of the so-called alternative fuel sources in order to answer the demand of preserving the environment. One of the highest possible sources of this alternative fuel is ethanol, or that fuel which is derived from corn.
Ethanol, also known as ethyl alcohol or grain alcohol or more commonly referred to simply as alcohol, is a flammable, colorless, and slightly toxic chemical compound which emits a sweet odor similar to that from most perfumes. This is that type of alcohol that is found in alcoholic beverages. Moreover, this ethanol can also be used as fuel additives, which is what is being introduced in the markets nowadays.

Brazil has the largest national ethanol fuel industries. Gasoline sold in Brazil has at least 20% of ethanol and hydrous ethanol used as fuel. This turnabout in the success of the ethanol fuel in Brazil was due to their almost 30 years of continuous research and study on the effects and other possibilities of the said fuel and still continuing research on the fuel’s compatibility with the many different engine types. Due to this, almost 50% of the cars in Brazil are able to use almost 100% ethanol as fuel. Flex fuel engines can work either with all ethanol or all gasoline or a mixture of both to give the users the optimum performance of their vehicle.

This trend has started to find its way into the international market. In the US, many studies are being conducted to try the said fuel. According to the Renewable Fuels Association (RFA) about 107 biorefineries in the US have the capacity to produce up to 5.1 billion gallons of ethanol per year.

Ethanol production would mean additional job opportunities in the field of agriculture and in the manufacturing industry. Also, since ethanol creates very little pollution when burned, this would be equal to lesser pollution and thus, cleaner air. Lesser pollution would also lessen the effects of global warming.

Because of the noise that ethanol fuel is making, the ethanol producers are slowly getting the support that they need in the campaign of promoting their product. The National Corn Growers Association (NCGA) lowered their heads to the lawmakers and put an end on costly budget proposals that could have triggered direct crop subsidy payments, instead they opted for another mode of action to tie some subsidies to revenue rather than production levels.
Many of the known automobile manufacturers have also joined in the talks regarding the issue. Still wary on the effects of this fuel upon the make up of their products and the condition of the probable alterations on some of the important vehicular parts like the Mercedes radiator they testified before the House Energy and Commerce subcommittee on energy and air quality

Advantages and Disadnvantages of biofuel

Biofuel is derived from biomass — recently living organisms or their metabolic byproducts, such as manure from cows. It is a renewable energy source, unlike other natural resources such as petroleum, coal, and nuclear fuels. Here are some advantages and disadvantages of this new fuel:

Advantages

- Renewable - vegetable oil derived

- Dramatically reduced emissions

- Carbon Neutral

- Biodegradable

- Non-toxic

- Less noxious - fuel & exhaust emmisions

- Used directly in unmodified diesel engine

- Biodegradable

- Higher Lubricity - can prolong engine life

- High flashpoint - safer to store & transport

- Simple to make

- Used neat or blended in any ratio with petroleum diesel


Disadvantages

* Availability - very few outlets & manufacturers. Fuel giants have not explored / invested in emerging biofuel technology such as algal oil / biologically produced fuels
* Poorly made biodiesel of low quality can cause engine problems
* Producing biodiesel without proper equipment and safety precautions can be dangerous



Green fuel

* Renewable - Biodiesel is derived from vegetable oil which is essentially grown - a sustainable resource that will not run out. Petroleum diesel is derived from crude oil, which is finite and will eventually run out.

* Carbon Neutral - Biodiesel use does not lead to any overall change in the amount of CO2 in the atmosphere. The vegetables from which the oil has been extracted remove CO2 from the atmosphere to grow. When biodiesel is burned the CO2 is released back into atmosphere.

* Less noxious, non-toxic - Biodiesel lacks the unpleasant odour of petroleum diesel and exhaust emissions smell like a barbecue! Users can expect a near 100% reduction in Sulphur dioxide (SO2), 40-60% reduction in soot & particulates, 10-50% reduction in Carbon monoxide, and a reduction in all Poly Aromatic Hydrocarbons PAHs - Phenanthren -97%, Benzofluoroanthen -56%, Benzapyren -71%, Aldehydes & Aromatics -13%.

* Unlike petroleum diesel, it is biodegradable.



Other advantages

* Simple to make, and can be produced from waste vegetable oil.
* Classed as non-hazardous because it is non-toxic and has a high flash-point.
* Burns more efficiently than petroleum diesel.
* Substantially higher lubricity means it can reduce engine wear and hence prolong engine life.

vegetable oil for fuel history

The first known use of vegetable oil as fuel for a diesel engine was a demonstration of an engine built by the Otto company and designed to burn mineral oil, which was run off of pure peanut oil at the 1900 World's Fair. When Rudolf Diesel invented the diesel engine, he designed it to run on peanut oil but it was soon discovered that it would operate on cheaper petroleum oil. In a 1912 presentation to the British Institute of Mechanical Engineers, he cited a number of efforts in this area and remarked, "The fact that fat oils from vegetable sources can be used may seem insignificant today, but such oils may perhaps become in course of time of the same importance as some natural mineral oils and the tar products are now."

Periodic petroleum shortages spurred research into vegetable oil as a diesel substitute during the 30s and 40s, and again in the 70s and early 80s when straight vegetable oil enjoyed its highest level of scientific interest. The 1970s also saw the formation of the first commercial enterprise to allow consumers to run straight vegetable oil in their automobiles, Elsbett of Germany. In the 1990s Bougainville conflict, islanders cut off from oil supplies due to a blockade used coconut oil to fuel their vehicles.

Academic research into straight vegetable oil fell off sharply in the 80s with falling petroleum prices and greater interest in biodiesel as an option that did not require extensive vehicle modifications.

Autogas

Autogas is the common name for liquified petroleum gas when it is used as a fuel in internal combustion engines in vehicles. The same equipment is also used for similar engines in stationary applications such as generators.

Autogas is widely used as a "green" fuel as it decreases exhaust emissions (less 20 % CO2) . It has an octane rating (MON/RON) that is between 90 and 110 and an energy content (higher heating value—HHV) that is between 25.5 megajoules per litre (for pure propane) and 28.7 megajoules per litre (for pure butane.)

In countries where petrol is called petrol rather than gasoline, it is common for autogas to be simply referred to as gas. This can be confusing for people from countries where petrol is called gasoline, as they often use the abbreviation gas to refer to petrol. In the United States, autogas is more commonly known under the name of its primary constituent, propane.


Vehicle manufacturers

Toyota made a number of LPG engines in their 1970s M, R, and Y engine families.

Currently, a number of automobile manufacturers—Citroën, Fiat, Ford, Hyundai, General Motors (including Daewoo, Holden, Opel/Vauxhall, Saab), Peugeot, Renault, Toyota and Volvo—have OEM bi-fuel (dual fuel) models that will run equally well on both LPG and petrol. See list of LPG cars.

Vialli have OEM LPG powered scooters and LPG powered mopeds that run equally well on LPG. Ford Australia have offered an LPG-only variant of their Falcon model since 2000.

MAN AG produces LPG buses.

Countries

Autogas enjoys great popularity in Australia, The Netherlands, Italy, Serbia, Poland, Hong Kong and Korea. The former Soviet republic of Armenia may, however, be the world leader in autogas use. The Armenian transport ministry estimates as much as 20 to 30% of vehicles use autogas compared to traditional gasoline, once again due to the fact that it offers a very cheap alternative to both diesel and petrol, being less than half the price of petrol and some 40% cheaper than diesel. The recent rises in oil-derived fuels has sharply raised the difference.


Europe

The european standard is EN 589


Australia

LPG is popular in Australia, in part due to it being less than half the price of petrol in urban areas. The four major local manufacturers (Ford, Holden, Mitsubishi and Toyota) offer it in some models of their locally made large cars. All factory autogas vehicles are dual fuel vehicles, with the exception of the E-Gas Ford Falcon model, which runs on autogas only.

Autogas is especially popular with taxis, except in remote areas where transportation costs make autogas prices uncompetitive.

Whilst LPG is currently excise-free, an excise on LPG starting at 2.5 cents per litre in 2011 will be placed, which will increase incrementally to 12.5 cents per litre (as opposed to the 38 cpl excise on petrol) by 2015. This will be offset somewhat by a AU$2000 subsidy that was implemented in 2006 for private motorists to convert their cars to LPG.The subsidy does not presently apply to business vehicles or vehicles with a Gross Vehicle Mass of over 3500 kilograms but lobbyists are trying to get that changed. On top of the subsidy to be provided by the Australian federal government, the Western Australian government will also provide motorists with a AU$1000 subsidy under the long-running LPG subsidy scheme.


System types

The different autogas systems generally use the same type of filler, tanks, lines and fittings but use different components in the engine bay. Some injection systems use special tanks with circulation pumps and return lines similar to petrol fuel injection systems.

There are three basic types of autogas system. The oldest of these is the conventional converter-and-mixer system, which has existed since the 1940s and is still widely used today. The other two types are known as injection systems, but there are significant differences between the two.

A converter-mixer system uses a converter to change liquid fuel from the tank into vapour, then feeds that vapour to the mixer where it is mixed with the intake air.

Vapour phase injection systems use a converter in much the same way as with a mixer, but have a series of electrical shutoff solenoids and nozzles (collectively referred to as injectors) that are controlled by a computer. The computer works in much the same way as a petrol fuel injection computer. This allows much more accurate metering of fuel to the engine than is possible with mixers, improving economy and/or power while reducing emissions.

Liquid phase injection systems do not use a converter, but instead deliver the liquid fuel into a fuel rail in much the same manner as a petrol injection system. These systems are still very much in their infancy. Because the fuel vapourises in the intake, the air around it is cooled significantly. This increases the density of the intake air and can potentially lead to substantial increases in engine power output, to the extent that such systems are usually de-tuned to avoid damaging other parts of the engine. Liquid phase injection has the potential to achieve much better economy and power plus lower emission levels than are possible using mixers or vapour phase injectors.


System components

Filler

The fuel is transferred into a vehicle tank as liquid by connecting the bowser at the filling station to the filler fitting on the vehicle.

The type of filler used varies from country to country:

* The type used in Australia and the USA has an ACME threaded fitting onto which the bowser nozzle is screwed before the trigger is pulled to establish a seal then transfer fuel.
* The type used in other countries is the Bajonett.

The fill valve contains a check valve so that the liquid in the line between the filler and the tank(s) does not escape when the bowser nozzle is disconnected.

In installations where more than one tank is fitted, T-fittings may be used to connect the tanks to one filler so that the tanks are filled simultaneously. In some applications, more than one filler may be fitted, such as on opposite sides of the vehicle. These may be connected to separate tanks, or may be connected to the same tanks using T-fittings in the same manner as for connecting multiple tanks to one filler.


Hoses, pipes and fittings

The hose between the filler and tank(s) is called the fill hose or fill line. The hose or pipe between the tank(s) and the converter is called the service line. These both carry liquid under pressure.

The flexible hose between the converter and mixer is called the vapour hose or vapour line. This line carries vapour at low pressure and has a much larger diameter to suit.

Where the tank valves are located inside an enclosed space such as the boot of a sedan, a plastic containment hose is used to provide a gas-tight seal between the gas components and the inside of the vehicle.

Liquid hoses for LPG are specifically designed and rated for the pressures that exist in LPG systems, and are made from materials designed to be compatible with the fuel. Some hoses are made with crimped fittings, while others are made using re-usable fittings that are pressed or screwed onto the end of the hose.

Rigid sections of liquid line are usually made using copper tubing, although in some applications, steel pipes are used instead. The ends of the pipes are always double-flared and fitted with flare nuts to secure them to the fittings.

Liquid line fittings are mostly made from brass. The fittings typically adapt from a thread in a component, such as a BSP or NPT threaded hole on a tank, to an SAE flare fitting to suit the ends of pipes or hoses.


Tank

Vehicles are often fitted with only one tank, but multiple tanks are used in a some applications.

The tanks have fittings for filling, liquid outlet, emergency relief of excess pressure, fuel level gauge and sometimes a vapour outlet. These may be separate valves mounted into a series of 3 to 5 holes in a plate welded into the tank shell, or may be assembled onto a multi-valve unit which is bolted into one large hole on a boss welded into the tank shell.

Modern fill valves are usually fitted with an automatic fill limiter (AFL) to prevent overfilling. The AFL has a float arm which restricts the flow significantly but does not shut it off entirely. This is intended to cause the pressure in the line to rise enough to tell the bowser to stop pumping but not cause dangerously high pressures. Before AFLs were introduced, it was common for the filler (with integral check valve) to be screwed directly into the tank, as the operator had to open an ullage valve at the tank while filling, allowing vapour out of the top of the tank and stopping filling when liquid started coming out of the ullage valve to indicate that the tank was full. Modern tanks are not fitted with ullage valves.

The liquid outlet is usually used to supply fuel to the engine, and is usually referred to as the service valve. Modern service valves incorporate an electric shutoff solenoid. In applications using very small engines such as small generators, vapour may be withdrawn from the top of the tank instead of liquid from the bottom of the tank.

The emergency pressure relief valve in the tank is called a hydrostatic pressure relief valve. It is designed to open if the pressure in the tank is dangerously high, thus releasing some vapour to the atmosphere to reduce the pressure in the tank. The release of a small quantity of vapour reduces the pressure in the tank, which causes some of the liquid in the tank to vapourise to re-establish equilibrium between liquid and vapour. The latent heat of vapourisation causes the tank to cool, which reduces pressure even further.

The gauge sender is usually a magnetically coupled arrangement, with a float arm inside the tank rotating a magnet, which rotates an external gauge. The external gauge is usually readable directly, and most also incorporate an electronic sender to operate a fuel gauge on the dashboard.



Valves

There are a number of types of valve used in autogas systems. The most common ones are shutoff or filterlock valves, which are used to stop flow in the service line. These may be operated by vacuum or electricity. On dual-fuel systems with a petrol carburettor, a similar shutoff valve is usually fitted in the petrol line between the pump and carburettor.

Check valves are fitted in the filler and on the fill input to the fuel tank to prevent fuel flowing back the wrong way.

Service valves are fitted to the outlet from the tank to the service line. These have a tap to turn the fuel on and off. The tap is usually only closed when the tank is being worked on. In some countries, an electrical shutoff valve is built into the service valve.

Where multiple tanks are fitted, a combination of check valves and a hydrostatic relief valve are usually installed to prevent fuel from flowing from one tank to another. In Australia, there is a common assembly designed for this purpose. It is a combined twin check valve and hydrostatic relief valve assembly built in the form of a T-fitting, such that the lines from the tanks come into the sides of the valve and the outlet to the converter comes out the end. Because there is only one common brand of these valves, they are known colloquially as a Sherwood valve.


Converter

The converter (also known as vapouriser) is a device designed to change the fuel from a pressurised liquid to a vapour at around atmospheric pressure for delivery to the mixer or vapour phase injectors. Because of the refrigerant characteristic of the fuel, heat must be put into the fuel by the converter. This is usually achieved by having engine coolant circulated through a heat exchanger that transfers heat from that coolant to the LPG.

There are two distinctly different basic types of converter for use with mixer type systems. The European style of converter is a more complex device that incorporates an idle circuit and is designed to be used with a simple fixed venturi mixer. The American style of converter is a simpler design which is intended to be used with a variable venturi mixer that incorporates an idle circuit.

Engines with a low power output such as; scooters, quad bikes and generators can use a simpler type of convertor (also known as governor or regulator). These convertors are fed with fuel in vapour form. Evaporation takes place in the tank where refrigeration occours as the liquid fuel boils. The tanks large surface area exposed to the ambient air temperature combined with the low power output (fuel requirment) of the engine make this type of system viable. The refrigeration of the fuel tank is proportional to fuel demand hence this setup is only used on smaller engines. This type of convertor can either fed with vapour at tank pressure (called a 2 stage regulator) or be fed via a tank mounted reguator at a fixed reduced pressure(called a single stage regulator).


Mixer

The mixer is the device that mixes the fuel into the air flowing to the engine. The mixer incorporates a venturi designed to draw the fuel into the airflow due to the movement of the air.

Mixer type systems have existed since the 1940s and some designs have changed little over that time. Mixers are now being increasingly superceeded by injectors.


Vapour phase injectors

Most vapour phase injection systems mount the solenoids in a manifold block or injector rail, then run hoses to the nozzles, which are screwed into holes drilled and tapped into the runners of the intake manifold. There is usually one nozzle for each cylinder. Some vapour injection systems resemble petrol injection, having separate injectors that fit into the manifold or head in the same manner as petrol injectors, and are fed fuel through a fuel rail.


Liquid phase injectors

Liquid phase injectors are mounted onto the engine in a manner similar to petrol injectors, being mounted directly at the inlet manifold and fed liquid fuel from a fuel rail.


Electrical and electronic controls

The are four distinct electrical systems that may be used in autogas systems - fuel gauge sender, fuel shutoff, closed loop feedback mixture control and injection control.

In some installations, the fuel gauge sender fitted to the autogas tank is matched to the original fuel gauge in the vehicle. In others, an additional gauge is added to display the level of fuel in the autogas tank separately from the existing petrol gauge.

In most modern installations, an electronic device called a tachometric relay or safety switch is used to operate electrical shutoff solenoids. These work by sensing that the engine is running by detecting ignition pulses. Some systems use an engine oil pressure sensor instead. In all installations, there is a filterlock (consisting of a filter assembly and a vacuum or electric solenoid operated shutoff valve) located at the input to the converter. In European converters, there is also a solenoid in the converter to shut off the idle circuit. These valves are usually both connected to the output of the tachometric relay or oil pressure switch. Where solenoids are fitted to the outputs of fuel tanks, these are also connected to the output of the tachometric relay or oil pressure switch. In installations with multiple tanks, a switch or changeover relay may be fitted to allow the driver to select which tank to use fuel from. On dual-fuel systems, the switch used to change between fuels is used to turn off the tachometric relay.

Closed loop feedback systems use an electronic controller that operates in much the same way as in a petrol fuel injection systems, using an oxygen sensor to effectively measure the air/fuel mixture by measuring the oxygen content of the exhaust and control valve on the converter or in the vapour line to adjust the mixture. Mixer type systems that do not have a closed loop feedback fitted are sometimes referred to as open loop systems.

Injection systems use a computerised control system which is very similar to that used in petrol injection systems. In virtually all systems, the injection control system integrates the tachometric relay and closed loop feedback functions.


Converter-and-mixer system operation

The designs of converters and mixers are matched to each other by matching sizes and shapes of components within the two.

In European style systems, the size and shape of the venturi is designed to match the converter. In American style systems, the air valve and metering pins in the mixer are sized to match the diaphragm sizes and spring stiffnesses in the converter. In both cases, the components are matched by the manufacturers and only basic adjustments are needed during installation and tuning.

An autogas carburettor simply consists of a throttlebody and a mixer, sometimes fitted together using an adapter.

Cold start enrichment is achieved by the fact that the engine coolant is cold when the engine is cold. This causes denser vapour to be delivered to the mixer. As the engine warms up, the coolant temperature rises until the engine is at operating temperature and the mixture has leaned off to the normal running mixture. Depending on the system, the throttle may need to be held open further when the engine is cold in the same manner as with a petrol carburetor. On others, the normal mixture is intended to be somewhat lean and no cold-start throttle increase is needed. Because of the way enrichment is achieved, no additional choke butterfly is required for cold starting with LPG.

The temperature of the engine is critical to the tuning of an autogas system. The engine thermostat effectively controls the temperature of the converter, thus directly affecting the mixture. A faulty thermostat, or a thermostat of the wrong temperature range for the design of the system may not operate correctly.

The power output capacity of a system is limited by the ability of the converter to deliver a stable flow of vapour. A coolant temperature lower than intended will reduce the maximum power output possible, as will an air bubble trapped in the cooling circuit or complete loss of coolant. All converters have a limit, beyond which mixtures become unstable. Unstable mixtures typically contain tiny droplets of liquid fuel that were not heated enough in the converter and will vapourise in the mixer or intake to form an excessively rich mixture. When this occurs, the mixture will become so rich that the engine will flood and stall. Because the outside of the converter will be at or below zero degrees Celsius when this happens, water vapour from the air will freeze onto the outside of the converter, forming an icy white layer. Some converters are very suceptible to cracking when this happens.


Performance

The Yellow-Checker-Star taxi fleet of Las Vegas, NV is a well known propane user. These taxis are mostly production gasoline Crown Victoria conversions. When the larger propane fuel tank replaces the smaller gasoline tank, about 1/8 of the trunk space is lost. Maximum distance varies between 250 to 320 miles on one full tank. Fuel capacity varies a great deal with ambient temperature. In the coldest desert winter nights taxis might travel up to 400 miles or more. But in the hotest summer days taxis might achieve only 180 miles. When it is very hot, refueling requires extra time. This can cause long lines to form at refueling stations, particularly during shift changes.

It's a common rule of thumb in Australia that a dual fuel car will use about 20-30% more fuel than an equivalent petrol car, and has about 20-30% less power. Modern injection systems are making the gap smaller, however, as do dedicated LPG systems, since they don't have to be able to run both LPG and petrol.


LPG injection for diesel vehicles

The performance, economy and emission profile of diesel engines can be improved by injecting a small quantity of LPG into the inlet manifold. It is claimed that the LPG increases the burning efficiency of the diesel fuel from typically 75-85%, to 95-98%.

The systems typically operate by metering a small quantity of LPG, at a pressure slightly above atmospheric, into the intake manifold, where it enters the combustion chamber and is ignited with the diesel. LPG flow is regulated to ensure smooth operation, and will typically only deliver LPG under power.

Some companies claim a 10% to 20% increase in power and torque, and a reduction in overall fuel costs. Any actual savings are dependent on the relative cost of diesel versus LPG. In Australia, where diesel costs substantially more then LPG, savings of 10 to 20% are claimed.

Lean burn

Lean burn is an internal combustion of lean air-fuel mixtures. It happens at very high air-fuel ratios (up to 65:1), so the mixture has considerably less amount of fuel in comparison to stoichiometric combustion ratio (14.6:1 for petrol).

The engines designed for lean burning can employ higher compression ratios and thus provide better performance, efficient fuel use and low exhaust emissions than those found in conventional petrol engines. Ultra lean mixtures with very high air-fuel ratios can only be achieved by Direct Injection engines.

The main drawback of lean burning is the large amount of NOx being generated, so a complex catalytic converter system is required. Lean burn engines do not work well with modern 3-way catalytic converters, which require a balance of pollutants at the exhaust port in order to carry out both oxidation and reduction reactions, so most modern engines run at or near the stoichiometric point.


Chrysler Lean Burn computer

From the late 1970s to mid 1980s, Chrysler equipped many of its North American production cars with a spark control computer which it called the Lean Burn Computer on the large sticker on the unit.

Mounted on the air filter housing of most rear-wheel drive cars Chrysler produced during this time, it was responsible for adjusting spark timing based on manifold vacuum, engine speed, engine temperature and incoming air temperature; by doing this, Chrysler eliminated the traditional vacuum and centrifugal timing advance mechanisms used on distributors in order to provide more accurate spark timing. It also provided drive for the ignition coil directly, eliminating the separate ignition module.

Based on an early computer system, most Lean Burn computers were an open-loop emissions control system with no provided diagnostic port or "Check Engine" warning light, were difficult to troubleshoot, and were greatly responsible for the poor reliability reputation which dogged Chrysler at the time.

Many Lean Burn computers were replaced with the more reliable electronic ignition module and centrifugal/vacuum advance distributors used on earlier Chrysler vehicles, almost universally to improvements in fuel economy and driveability.


Heavy-duty gas engines

Lean burn concepts are often used for the design of heavy-duty natural gas, biogas, and liquefied petroleum gas (LPG) fuelled engines. These engines can either be full-time lean burn, where the engine runs with a weak air-fuel mixture regardless of load and engine speed, or part-time lean burn (also known as "lean mix" or "mixed lean"), where the engine runs lean only during low load and at high engine speeds, reverting to a stoichiometric air-fuel mixture in other cases.

Heavy-duty lean burn gas engines admit as much as 75% more air than theoretically needed for complete combustion into the combustion chambers. The extremely weak air-fuel mixtures lead to lower combustion temperatures and increased forced induction possibilities (that would otherwise be limited by high exhaust gas temperatures), leading to higher theoretical efficiencies when compared to engines running on a stoichiometric air-fuel mixture.


Honda lean burn systems

One of the newest lean-burn technologies available in automobiles currently in production uses very precise control of fuel injection, a strong air-fuel swirl created in the combustion chamber, a new linear air-fuel sensor (LAF type O2 sensor) and a lean-burn NOx catalyst to further reduce the resulting NOx emissions that increase under "lean-burn" conditions and meet NOx emissions requirements.

This stratified-charge approach to lean-burn combustion means that the air-fuel ratio isn't equal throughout the cylinder. Instead, precise control over fuel injection and intake flow dynamics allows a greater concentration of fuel closer to the spark plug tip (richer), which is required for successful ignition and flame spread for complete combustion. The remainder of the cylinders' intake charge is progressively leaner with an overall average air:fuel ratio falling into the lean-burn category of up to 22:1.

The older Honda engines that used lean burn (not all did) accomplished this by having a parallel fuel and intake system that fed a pre-chamber the "ideal" ratio for initial combustion. This burning mixture was then opened to the main chamber where a much larger and leaner mix then ignited to provide sufficient power. During the time this design was in production this system (CVCC, Compound Vortex Controlled Combustion) primarily allowed lower emissions without the need for a catalytic converter. These were carburated engines and the relative "imprecise" nature of such limited the MPG abilities of the concept that now under MPI (Multi-Port fuel Injection) allows for higher MPG too.

The newer Honda stratified charge (lean burn engines) will operate on air-fuel ratios as high as 22:1. The amount of fuel drawn into the engine is much lower than a typical gasoline engine which operates at 14.7:1. That being the chemical stoichiometric ideal for complete combustion when averaging gasoline to be the petrochemical industries' accepted standard of C6H8.

This lean-burn ability by the necessity of the limits of physics, and the chemistry of combustion as it applies to a current gasoline engine must be limited to light load and lower RPM conditions. A "top" speed cut-off point is required since leaner gasoline fuel mixtures burn slower and for power to be produced combustion must be "complete" by the time the exhaust valve opens.


Applications

* 1993–95 Civic VX
* 1998–2000 Civic Hx
* 2001 Civic Hx
* 2002–06 Civic Hybrid
* 2000–06 Insight


Diesel engines

All diesel engines are lean burning. This is essential to the way they ignite the fuel.

Ferox (fuel additive)

Ferox is a fuel additive. It was developed by Wesley Parish in 1985 from work done on experimental burn rate modifiers for solid rocket propellant systems used in the aerospace industry. Ferox was originally designed to lengthen the life engines. Until recently, it has been used predominantly in the marine, mining, and trucking industries. It is now used as a fuel additive in common automobile engines using gasoline, diesel, and others. The newest form is in a small tablet that is added with fuel into the tank to be dissolved.

There is evidence that ferox can lower polluting emissions, improve gas mileage, and reduce deposit build-up. There are also claims of prolonging engine life. However, the extent of these benefits for average fuel consumers is still not clear.

The product has been registered with the Environmental Protection Agency.

Ferox works as a catalyst, which lowers the activation energy of the rate determining step to break down build-up within the engine. This allows the carbon deposits to burn off at much lower temperatures.

Hydrogen fuel injection

Hydrogen Fuel Injection, or HFI, is a system to reduce exhaust emissions of internal combustion engines and improve fuel economy. HFI systems work by injecting hydrogen as a combustion enhancement into the intake manifold of an internal combustion engine to achieve these benefits. A small amount of hydrogen added to the intake air-fuel charge enhances the flame velocity and thus permits the engine to operate with leaner air-to-fuel mixture than otherwise possible. The result is lower pollution with more power and better mileage.

A simplified single-step combustion reaction is represented as: [FUEL] + [HYDROGEN] + [AIR] -> HC + CO + CO2 + H2O + NOx

For incomplete combustion, the above results in exhaust products including unburned hydrocarbons (HC) and carbon monoxide (CO). The NOx is formed mainly from the combustion air, and is highly temperature-dependent.

In 1974 John Houseman and D.J Cerini of the Jet Propulsion Laboratory, California Institute of Technology produced a report for the Society of Automotive Engineers entitled "On-Board Hydrogen Generator for a Partial Hydrogen Injection Internal Combustion Engine". In the same year, F.W. Hoehn and M.W. Dowy, also of the Jet Propulsion Lab, prepared a report for the 9th Intersociety Energy Conversion Engineering Conference, entitled "Feasibility Demonstration of a Road Vehicle Fueled with Hydrogen Enriched Gasoline." This research utilized onboard storage tanks to supply the hydrogen combustion enhancement.

More recent investigations have highlighted the potential for pollutant reduction. Research performed by scientists at the University of Birmingham, United Kingdom, released a study in June of 1995 at the HYPOTHESIS Conference at the University of Cassino, Italy in which it was presented that "hydrogen, when used as a fractional additive at extreme lean engine operation, yields benefits in improved combustion stability and reduced nitrogen oxides and hydrocarbon emissions." Similar results have been presented by a team of scientists representing the Department of Energy Engineering, Zhejiang University, China in the Spring of 1997 at an international conference held by the University of Calgary. Practical tests have been performed by California Environmental Engineering (CEE), The American Hydrogen Association Test Lab and Corrections Canada in which reduction in toxic exhaust emissions and fuel consumption were realized.

Commercially, Canadian Hydrogen Energy Company, LTD, produces an HFI system which generates hydrogen during vehicle operation by electrolyzing water (from an onboard storage tank) using power from the vehicle's electrical system. In dynamometer tests with 1992 60 series diesel engine fueled by low-sulphur (<15 PPM) diesel fuel, the system draws a maximum of 35 amps (12V DC) and yields 4.44% reduced fuel consumption, 6.17% reduced HC emissions, 0.39% reduces CO emissions, 4.34% reduced NOx emissions, and 7.0% reduced PM (particulate matter) emissions.

Publicly, Canadian Eagle Research Company produces the HyZor on-board electrolyzer that is comparable to coexisting commercial devices primarily being scaled down to fit Sedans, Coupes, SUV's, and Hybrids. A unique feature of the system is its design not to remove oxygen giving the output gas properties extremely similar to the HFI system while eliminating the required ducting components necessary to separate oxygen. These systems are fully automated only requiring occasional refills of distilled water when the system informs the driver by dash mounted led’s controlled by an electronic circuit integrated with the vehicles ignition.

Alcohol fuel

Rising energy prices and global warming have led to increased interest in alternative fuels. Alcohol has been used as a fuel in other points in history but fossil fuels have become the dominant energy resource for the modern world. Generally speaking, the chemical formula for alcohol fuel is CnH2n+2O. The larger n is, the higher the energy density.

The first four aliphatic alcohols (methanol, ethanol, propanol, and butanol) are of interest as fuels because they can be synthesized biologically, and they have characteristics which allow them to be used in current engines. One advantage shared by all four alcohols is octane rating. Biobutanol has the advantage that its energy density is closer to gasoline than the other alcohols (while still retaining over 25% higher octane rating).

Alcohol fuels are usually of biological rather than petroleum sources. When obtained from biological sources, they are sometimes known as bioalcohols (e.g. bioethanol). It is important to note that there is no chemical difference between biologically produced alcohols and those obtained from other sources. However, ethanol that is derived from petroleum should not be considered safe for consumption as this alcohol contains about 5% methanol and may cause blindness or death. This mixture may also not be purified by simple distillation, as it forms an azeotropic mixture.

Bioalcohols are still in developmental and research stages. Use of optimized crops with higher yields of energy, elimination of pesticides and fertilizers based on petroleum, and a more rigorous accounting process will help improve the feasibility of bioalcohols as fuels.