Techtrend

Hybrid efficiency, gasoline power

Mazda’s SKYACTIV-G engine uses super-precise valve and fuel injection control to boost fuel economy to hybrid-like levels.

NEW YORK (CNNMoney.com) — Mazda recently unveiled a prototype Mazda2 subcompact that uses an all-new gasoline engine designed to get an estimated 70 mpg in Japanese fuel economy tests .That’s about the same fuel economy as a hybrid car but this car’s not a hybrid.

Because hybrid technology, with its big batteries and electric motors, is expensive, selling hybrids in large numbers can be a tough proposition. If cost limits the number of hybrids on the road, it also limits the impact on overall fuel use.

So Mazda wanted to figure out just how fuel efficient its gasoline engines could possibly be.

More efficient gas engines cost less to make and sell than hybrids or plug-ins. If they’re priced correctly and deliver the power and performance American drivers demand they could not only significantly cut gasoline consumption, they could be big money makers too.

In this engine — along with a host of design changes — Mazda engineers used two technologies already available on most new cars to achieve the extreme fuel economy: variable valve timing and direct fuel injection. Other automakers are piling on technologies like tubocharging, automatic start-stop and high-tech transmissions to push the fuel economy of their “ordinary” gasoline-power cars further, too.

Mazda’s not saying if this specific car is destined for sale in the U.S. but the basic engine design can readily be “scaled up” to larger sizes, a Mazda engineer said. Mazda plans to use an engine like this in a mid-sized sedan that will go on sale in the U.S. within the next couple of years.

With technologies like these, gasoline power is likely to stick around for the foreseeable future.

Variable valve timing. Traditionally, intake and exhaust valves open and close at certain set times as the pistons move inside the engine. Now, as in the case of the hyper-efficient Mazda engine, computers can vary when the valves open and close depending on performance demands.

With that kind of control, engineers can do all sorts of things with the air flow coming into and out of the cylinder. For instance, in the Mazda engine, extra cool air can be allowed in to flush out hot exhaust gases, cooling the cylinder so incoming gasoline doesn’t ignite too soon.

Direct injection. Fuel injection has been used for years, but direct fuel injection, squirting bursts of gasoline in each cylinder where the combustion happens, is the latest take on the technology. This development allows for gasoline combustion to be much more precisely controlled and the energy produced to be more efficiently harnessed by the engine.

For instance, in the Mazda engine, direct injection is used to create a fuel-rich cloud just around the spark plug where the burn starts then spreads to more thinly-fueled areas elsewhere in the cylinder.

Downsize and boost. Turbocharging allows a small engine to do the work of a bigger one. A smaller tubocharged engine can get 20% better fuel economy than a larger engine with similar power output said Kregg Wiggins, who heads powertrain operations in North America for the auto industry supplier Continental.

Case in point, the Ford Taurus SHO with EcoBoost. This car gets more than 100 more horsepower from the same size engine as the base Taurus. Since a smaller engine uses less gasoline, the more powerful SHO’s fuel economy is exactly the same as the base Taurus, according to EPA estimates.

Automatic start-stop. In hybrid cars, when you pull up to a red light or stop sign, the engine shuts off until you take your foot off the brake and put it back on the gas pedal. You can expect this technology to become more common on non-hybrid models, as well.

The challenge for engineers is to make start-stop palatable in regular cars that don’t have big hybrid batteries and electric motors to help get the car rolling. Without those, starting the engine would usually mean a big shudder and momentary loss of accessory power to things like the radio.
0:00 /2:21Ford Fiesta rolls into U.S.

“You need a fuel injection system that is start-stop ready,” said Frank Furster, a project manager for Bosch North America, a supplier company that makes start-stop systems.

Engine computers must be able to detect the position of each piston in the engine so fuel can be injected into cylinders that are in the right position to begin pushing without having crank the engine much.

Also, like a hybrid, the cars can use “regenerative braking,” in which braking power is used to generate electricity. That extra power is used to keep the radio, air conditioning and lights going on each time the car cranks up again.

Start-stop technology provides gains up to 15% in real-world city driving, Furster said, but the impact doesn’t show up in U.S. EPA fuel tests because those tests are designed with minimal idling.

Transmissions. Some new cars, like the Ford Fiesta, use a twin-clutch transmission. These automatic transmissions have clutches, like manual transmissions, but they have a pair of them allowing things that would be impossible in a stick-shift car. In a twin-clutch, at least one clutch is always closed, sending power to the wheels at all times with no idle-time in between gears.

Transmissions like this offer a three to five percent gain in efficiency over a manual transmission said Continental’s Wiggins.

Estimates for fuel economy gains from technologies like these are always extremely broad because they all depend on they are applied and what other technologies are being used at the same time.

At the same time, dual-clutch, like turbocharging and direct injection, offers better performance. That’s good for the automakers because offering better efficiency and better performance is what will sell cars.

“Our assumption is consumers are not willing to put up with a loss,” Wiggins said. To top of page

Original article: http://money.cnn.com/2010/11/02/autos/gas_engine_improvements/index.htm

U.K. consortia chase ultralow-carbon targets

Interest in flywheel hybrids has spread from F1 racing’s KERS (kinetic energy recovery systems).

Ford, Jaguar Land Rover, and a number of specialist companies—together with universities that have formed technology-led consortia to develop greener vehicles—are to receive cash support from the U.K. government-backed Technology Strategy Board (TSB).

Six consortia will run extensive innovation projects designed to strengthen the U.K.’s ultralow-carbon capability, with particular focus on supply chain development. They secured the funding via a competition developed by the TSB in partnership with the Department for Business Innovation and Skills (BIS) and the Office for Low Emissions (OLEV).

U.K. Transport Secretary Philip Hammond said £24m would go to the consortia. Speaking at the recent Low Carbon Vehicles 2010 event at Millbrook Proving Ground north of London, Hammond said: “I congratulate the six winners for their fresh and innovative solutions to the low-carbon challenge. These projects represent cutting-edge technology that has the potential to transform the way we travel in a way that will stimulate a vital and growing market.”

Each project has been designed to optimize and improve opportunities for companies that manufacture components and systems as part of the automotive supply chain and involve both large and small- to medium-size enterprises. Each project had to demonstrate a credible route to market with the associated opportunities for high-tech jobs.

One of the projects is VIPER (Vehicle Integrated Powertrain Energy Recovery), with Jaguar Land Rover as lead. Others involved include Ford, BP, Imperial College London, and the University of Nottingham. The project’s aim is to show how a CO2 emissions reduction of 4.5% could be achieved over a broad range of new vehicles by optimizing control of heat energy in current conventional vehicles.

Suppliers with the VIPER project are to develop new technologies to harness, manage, and store heat energy and integrate it into a practical demonstrator. A prototype Land Rover will be used to demonstrate the effectiveness of the consortium’s work.

Expertise in computational and experimental techniques is to be combined with engineering service suppliers to develop new and efficient methods for the optimization of future vehicles. These should be a majority of new vehicles by 2020.

Jaguar Land Rover is also involved in the REEV (Range Extended Electric Vehicle) consortium together with Lotus Cars, Nissan, EVO Electric, Xtrac, Think Global, and Axeon. The project aims to deliver REEV products while developing four fledgling U.K. suppliers of novel ultralow-carbon technologies. The consortium companies are to work together to develop advanced electric powertrains and a greater understanding of the commercial requirements needed for high-performance electric and range-extended vehicles. The work will accelerate the development of new technologies and key commodities while laying the foundations for a globally competitive supply base, according to a statement by the partners.

The program (known as REEVolution) is the next phase of the Jaguar Land Rover-led Limo Green project. This involves a range-extended hybrid-electric Jaguar XJ prototype. It delivers sub-120 g/km tailpipe CO2, a fuel consumption of 4.9 L/100 km, and a top speed of 180 km/h (112 mph). Overall range is 600 mi (965 km) and in pure EV mode 30 mi (48 km). Participants in the new project will develop components and systems, as demonstrated on Limo Green, to global levels of quality and reliability required for production. It is expected to deliver a CO2 emissions reduction of up to 75%. Jaguar has not officially stated that it will produce a hybrid car but is understood to be considering the idea.

Ford is leading the consortium involved in the emissions Project CREO (CO2 Reduction through Emissions Optimization). Jaguar Land Rover is also involved in this initiative, as is Johnson Matthey, ITM Power (Trading), Revolve Technologies, Combustion, and the University of Bradford, University of Liverpool, and University of Birmingham. They will work to reduce or eliminate the 4% negative effect of a typical emissions control system on fuel consumption. The project will look at ways of redesigning the engine and aftertreatment system as a complete system. Novel aftertreatment techniques and new optimization tools will be developed.

Three technology demonstration vehicles will be built under Project CREO: gasoline and diesel cars and a diesel hybrid bus. The target is a 4% reduction in CO2 by 2015, rising to 15% by 2025.

Weight reduction remains a very significant route to reduced emissions, and AluMatCom (Aluminum Matrix Composite Materials for Vehicle Weight Reduction) is a consortium project that aims to do just that. Jaguar leads members including Composite Metal Technology, Textile Center of Excellence, and Antich and Sons. The project will examine the potential for using reinforcing fibers in cast-aluminum components to provide a material with the potential to deliver the strength and stiffness of steel but with the weight of aluminum. Members of the consortium will endeavor to demonstrate engineering, manufacturing, and commercial feasibility of the materials.

A range of technologies was shown at the Millbrook event, including a flywheel hybrid system for premium vehicles (FHPSV). It can add up to 60 kW of recovered energy to a vehicle, with 20% fuel-economy gains. Compared to conventional hybrid systems, flywheel hybrids reduce the number of energy conversions on board the vehicle, improving the efficiency of the regenerative braking system.

Rather than converting kinetic energy into electricity for storage in a battery, a small CVT (continuously variable transmission) connected to the car’s rear differential transfers the energy directly into a compact, high-speed flywheel. When the accelerator pedal is reapplied, the CVT transfers energy back to the wheels.

Project partners include Jaguar Land Rover, Flybrid Systems, Ford, Prodrive, Ricardo, Torotrak, and Xtrac. Flybrid Systems’ flywheel reaches 60,000 rpm to achieve a very high energy density, which allows it to be of compact design for efficient packaging. The CVT manages the flywheel’s speed and flow of kinetic energy. It is built by motor sport specialist Xtrac using Torotrak’s traction drive technology.

“Initial studies suggest that the cost will be half that of an equivalent battery-electric system,” said Torotrak CEO Dick Elsy. “The flywheel system provides a lot of scope for different operating calibrations. For example, in economy mode, it could be kept half charged to optimize energy recovery. In sport mode, it could be kept fully charged to deliver additional torque.”
Stuart Birch

Original article: http://www.sae.org/mags/AEI/8876

Start/stop shines spotlight on battery management

Hella’s dc-dc converter is one of the components that could help bring start/stop functions to the U.S.

Shutting off the engine at stoplights, rail crossings, and other places where drivers stop for a while can provide solid improvements in fuel economy. Most European carmakers have adopted this technology, and components suppliers are predicting that U.S. automakers will follow suit as they push to meet new fuel economy requirements.

The benefits are significant. “Based on experience in Europe, where more than a third of the cars use start/stop, you can see a 12-15% improvement in fuel economy,” said Mark Brainard, Vice President of Product Development at Hella Electronics.

Other suppliers are also focusing on the need for improved battery management. ZMDI recently introduced battery-control components as part of its corporate focus on energy conservation.

“When you decrease the amount of electrical energy, you’re also increasing the miles per gallon. A side benefit of efficient battery management is extending the lifetime of the battery,” said Carlo Rebughini, Executive Marketing Vice President at ZMDI. More efficient battery management also extends life when vehicles are parked for long periods, he added.

Many of the early adopters of start/stop technology are in Europe. “Europeans are more sensitive to fuel economy, and it has been easier to use start/stop on the manual transmissions that are in around 80% of European cars,” Brainard said. “There have been technical breakthroughs that make it adaptable to automatic transmissions.”

That could open up a huge market as North American automakers strive to meet new U.S. regulations for fuel economy. Hella predicts that usage will take off in two to three years, and some market analysts feel that growth rates will be around 50% after that. Brainard expects start/stop to be almost a standard feature by 2020.

ZMDI is responding with an integrated approach that includes a system basis chip, microcontroller, and extensive software. A measurement IC rounds out the package, which mounts on a battery cable.

Hella makes two components that meet market requirements. One is a bidirectional dc-to-dc converter that stabilizes electronics when the engine turns on and off. This device ensures that displays and lights don’t flicker so the changes appear more seamless to drivers. It also ensures that radios and systems including airbags function during transitions.

The other Hella component, an integrated battery sensor, provides advanced functions that will help ensure that the vehicle actually starts at all times, which is a key concern for car buyers. The module, which attaches to the battery’s negative terminal, houses sensors that monitor current to within 1% accuracy.

It also includes temperature- and voltage-monitoring sensors. Together, the components provide a lot of information including battery lifetimes.

“We have algorithms that give you status functions and can detect the status of battery health,” Brainard said. “If the sensor determines that battery aging or cold weather create risks that the car won’t start, we feed that information to the start/stop controller so it can tell whether it’s safe to shut the engine off or not.”

Though start/stop is still available on a small number of cars, design teams are already focusing on next-generation advances. Hella is working on systems that turn off when the car is slowing down, so it will coast to stop signs or down hills.

“That requires a whole new set of inputs and new algorithms. It can get you another 5-7% in fuel savings,” Brainard said. He predicts that the system will be ready around 2015.
Terry Costlow

Original article: http://www.sae.org/mags/AEI/9026

CPT sees big volumes in low-voltage micro-hybrid systems

The scalable VTES electric supercharger (shown in foreground) is capable of providing up to 25 kW of additional power to the crankshaft in less than one second. CPT believes the combination of supercharger and integrated starter-generator technologies can significantly advance micro-to-mild hybrid systems.

Hybrid electric vehicles have gained enormous credibility in recent years but the cost-to-benefit ratios of some are questionable. Diesel hybrids are an extreme example, with their impressive fuel consumption/emissions figures offset by the high cost of the diesel-electric powertrain. Sometimes the hybrid technology solution simply does not add up to high-volume commercial viability.

A potential alternative is further development of micro-hybrid systems. At the 22nd International AVL Conference in Graz, Austria, in early September, U.K. consultancy Controlled Power Technologies (CPT) put forward its views on the future of micro-hybrid technology. The conference, titled “Engine & Environment,” was organized by AVL List GmbH, which claims to be the world’s largest independent developer of vehicle powertrains.

Amongst those presenting technical papers for discussion was Guy Morris, CPT’s Engineering Director and Chief Technical Officer. He believes that in the current spectrum of hybrid development, there is a band of opportunity in the middle ground of so-called “micro-to-mild” technologies that can generate the level of cost:benefits that is essential for commercial success via economies of scale.

“Integrated starter-generators and electric superchargers are good examples of advanced 12-volt micro-hybrid technologies,” states Morris. “When applied simultaneously, these compact machines can help deliver a low-voltage equivalent to a mild hybrid solution that avoids the cost, weight, and packaging penalties of a full hybrid or high-voltage electric vehicle.”

According to Morris, the lower cost “micro/mild” solution also reduces the industry’s dependence on government subsidies that are often required to make such vehicles affordable under current market conditions.

Using a new generation of low-voltage micro-hybrid technologies and retaining a gasoline or diesel engine as the main driving force can bring a 25% fuel saving without incurring the expense that higher voltages and massive battery packs bring, he explained.

CPT’s core competencies include low-voltage power electronics, advanced control software, and the application of 12-24 V electrical machines to vehicle powertrains. Morris believes the opportunities for low-voltage solutions in high-volume sectors can, therefore, effectively tackle the critical “mild hybrid” middle ground, with low-voltage solutions generating technology and commercial opportunities. OEM interest is increasing, he noted.

At its Laindon headquarters east of London, CPT has developed two production-ready systems that meet these needs, explained Morris. One is the VTES (Variable Torque Enhancement System) supercharger, and the other is the SpeedStart B-ISG (Belt Integrated Starter Generator).

The recent availability of low-cost, low-voltage power electronic devices has, in particular, given a significant boost to the viability of such technologies, Morris told the Graz conference, where both were demonstrated.

He stated that CPT had engineered compact and highly scalable solutions that were previously unavailable. The company is able to manufacture these using industry standard processes, with minimal capital investment and tooling, he said.

The CPT technical paper presented at Graz concluded that a synergistic approach enables existing technology engine and transmission combinations to be aggressively downsized and down-speeded to support very significant vehicle CO2 reduction of more than 25%. The paper was jointly authored by Morris, Mark Criddle, Mike Dowsett, and Toby Heason from CPT, and by Dr. Paul Kapus and Matthias Neubauer from AVL—both of whom have worked closely with CPT since early 2009.

During that time, CPT has supported AVL in the development of an enhanced version of a low-voltage mild hybrid demonstrator. The vehicle is designed to deliver the best possible value for improving powertrain efficiency at an affordable system cost.

Based on a VW Passat sedan, the demonstrator incorporates a state-of-the-art AVL-developed 2.0-L gasoline engine currently delivering a claimed fuel consumption of 6.6 L/100km and CO2 emissions of 154 g/km. Those figures represent a 20% reduction from the 192 g/km of a series production Passat (MY2006) fitted with a 2.0-L TGDI engine. They are also close to the 146 g/km of the current Passat 2.0-L common rail TDI engine.

A significant feature of the demonstrator is its long gearing to enable down-speeding of the engine. Normally, this would result in unacceptable high-gear vehicle acceleration, but the integration of the VTES is designed to provide a significant dynamic performance boost. The system reacts immediately to transient load conditions by delivering up to 25 kW of additional power to the crankshaft in less than one second, even at very low engine speeds.

Next technology step is to further develop AVL’s efficient low-carbon ELC-hybrid concept by incorporating CPT’s SpeedStart system. In combination with the VTES electric supercharger, this will create what the companies describe as a cost-effective “micro/mild” hybrid system. They claim the system, when applied to a downsized 1.4-L variant of the ELC-hybrid power unit, would meet the European industry’s 2012 fleet-average 130 g/km CO2 emissions target.

The use of a “carbon enhanced” valve-regulated lead-acid (VRLA) battery will help maximize energy recuperation during deceleration.

CPT’s micro-hybrid technologies can be applied to a wide range of engines and are being evaluated by a number of carmakers. A major incentive is that in Europe the auto industry has less than two years in which to ensure that each manufacturer can meet the 130 g/km figure and the subsequent target of 95 g/km by 2020.

A similar deadline has been imposed in the U.S. with its first nationwide carbon emissions target of 250 g/mile (155 g/km) by 2012, with individual states able to impose tighter limits.

“The combination of low-voltage micro-hybrid technologies incorporating stop-start, brake regeneration, and electric boosting—as well as exhaust gas regeneration which we’re also working on for the longer term—can help minimize the additional cost of CO2 compliance to the consumer to between 1500 and 4000 euros within the 2015 to 2020 timeframe,” says Morris. “This compares with 6000 euros to more than 18,000 euros for a full hybrid or electric vehicle.”

To demonstrate the production-ready version of the SpeedStart system, CPT is undertaking a tour of European carmakers with an Audi A4 equipped with its next-generation B-ISG technology. The system includes intelligent torque and current control, plus significantly enhanced stop-start capabilities.

Denso out to make dumb red lights smart

Denso’s smart intersection capitalizes on GPS and DSRC technologies.

Have you ever experienced the case when arriving at a stop light, you see no other vehicle in the vicinity but you have to wait for the “normal” signal cycle? Have you ever been on a major surface street with a green light ahead, only to see the light cycle change to red upon your approach, with no one present on the cross streets? What a waste! And how about the occasions when you drive down a major urban arterial and catch stop light after stop light at each intersection? It seems like a waste of time, a waste of fuel, and an unnecessary burden on the environment. Isn’t there a better way?

According to a 2008 Texas Transportation Institute report, more than $87 billion and more than 4 billion h are wasted per year due to inefficient transportation networks. The solution is not to add more lanes; there simply is not enough land or money to do so. Instead, the focus should be on making the transportation system more efficient.

Several techniques are currently in place, including ramp metering, travel time websites, and actuated intersections. The U.S. Department of Transportation has initiated a substantial ITS (intelligent transportation systems) research program called IntelliDrive based on the belief that connectivity (vehicle to vehicles as well as vehicle to infrastructure) will improve the current situation further. The connectivity solution can provide localized and network-wide information, allowing transportation engineers to optimize traffic flow and efficiency.

The recent interest in IntelliDrive and vehicle connectivity has gone past previous notions of automatic collision notification, Internet browsing, and off-board navigation. Now, in addition to applying the 5.9 GHz ITS band for cooperative collision avoidance, other applications using connectivity between the vehicle and signalized intersections have emerged.

A group of researchers at Denso is investigating a number of ideas, including red light preemption and green light extension at individual signal-controlled intersections and along urban arterials. One of the researchers was slated to present a paper on their ideas at the SAE 2010 Convergence conference in Detroit Oct. 19-20. According to the paper, the best way to optimize traffic efficiency is to provide the control mechanisms with the most accurate and timely information possible. It’s not essential to have a central traffic control system in place—in some large networks, that would not be optimum, in fact.

These two solutions would use IntelliDrive connectivity to communicate full BSM (Basic Safety Message) information to the signal controller, updated not just once but at a 5- or 10-Hz rate. This approach would provide data not only about how many cars are approaching in which lane, but also whether they are accelerating, braking, and/or planning to turn (using vehicle dynamics and state). Data can also be gained about vehicle type. Vehicle type is important in cases such as when two fully loaded semi-tractor trailers are in a left-hand queue lane; they require longer intersection clearance times than a passenger car.

Red light preemption would use much of the system functionality that already would be in place for IntelliDrive-based V2X safety applications, including accurate vehicular positioning, two-way wireless message exchange, and coordination between roadside traffic control and the vehicle.

Today’s actuated intersections can already provide many elements of the fundamental functions of the preemption application concept. At traffic-actuated intersections, the signal timing changes from cycle to cycle depending on the detected approach of vehicular or pedestrian traffic. Cycle times and green extension times are most often predetermined by models for intersection throughput (e.g., the Minimum Delay Model and the Hybrid Model). What Denso researchers propose is to adapt the appropriate cycle times and extensions to achieve the “state optimum.” This concept provides the opportunity to modify traffic control parameters based not on average but instantaneous flow data obtained from oncoming vehicle (later, pedestrians, bicycles, motorcycles, etc.) broadcast messages. IntelliDrive data could be used either alone or in combination with other more traditional sensors in actuated intersection equipment and accommodate short-term fluctuations in traffic flow.

Envisioned is utilization of IntelliDrive 5.9-GHz based WAVE/DSRC communications systems to transfer data about the vehicles to the intersection controller through the Road Side Equipment (RSE). In the system described, only a single simple intersection model with a fully actuated controller is contemplated; there is only one approach from each of four directions at a perpendicular intersection with a single red, yellow, green signal matched to each approach. Of course, much more elaborate intersections and controller programming is possible, but the idea is to begin to understand how such simple systems interact and affect driver behavior before moving on to more complex situations.

Red light preemption and green light extension applications for both vehicle onboard equipment and roadside equipment have been successfully implemented and tested in a controlled environment at Denso’s Vista, CA, facility.
This article is based on SAE technical paper 2010-01-2317 by Roger Berg of Denso International America Inc.

Original article: http://www.sae.org/mags/AEI/8993