[Press Release]

Ancona, Italy. September 22, 2009. WHY, Wally Hermès Yachts, today unveils a revolutionary
approach to cruising in motor yachts with the presentation of a full size model of its first born, an
innovative 58 metre-long 38 metre-wide yacht, in Ancona’s shipyard.

Wally Hermès Yachts: a joint-venture.
WHY is the result of the joint-venture signed in June 2008 between Hermès and Wally, to develop a new type of motor yacht redefining the art of living on the sea. The iconic Parisian house and the iconic Monaco yacht brand formed an equal partnership whereby each company is fully involved in all aspects of the conception and design of each project. Pierre-Alexis Dumas, Artistic Director of Hermès says : “When we met, in autumn 2007, Luca Bassani Antivari, President of Wally had thought about asking Hermès to accessorise the interior of one of his boats. I was impressed by the daring of his projects. My instinct was to get on board with him and go and seek out new territories in yacht design, but I had no interest in speed.”

Luca Bassani Antivari explains: “What I’ve always liked about Hermès, aside from its intrinsic quality, is its audacity and radicalism; its desire to go beyond trends, to make no compromises and to maintain the authenticity of the house. Wally shares the same values, ‘Hermès-on-Land’, ‘Wally-on-Sea’: inevitably our paths had to cross.”

WHY 58×38
The common values of the two brands have led to a first yacht that offers an unparalleled living space at sea. WHY was developed to give life to this concept assembling a team of dedicated talents in design, engineering, and naval architecture.

Then the tried and tested Norwegian Ramform hull characterised by exceptional and unprecedented stability and volume and spotted by Luca Bassani Antivari, revealed itself as the ideal choice to be adapted to the WHY 58×38 project.

Following this unique adaptation, the decks and the interiors were developed in accordance with the fundamental credo of WHY, ‘form-equals-function’. Thus were born other innovations in the world of mega yachts: patios generously flooding the interior with natural light, photovoltaic panels on the glass hull sides, as well as on the roof opening, like Venetian blinds, a 25 metre-long forward end swimming pool, and a 36-metre aft deck beach.
WHY 58×38 offers comfort, privacy, stability, space, independence and sustainability.

Sustainability
“We are very interested in creating a yacht that will have a low environmental impact”, says Pierre-Alexis Dumas. “Its relationship with the sea must be respectful and easy. WHY intends to offer a new way of moving over water by creating an innovative way of managing and recycling its sources and uses of energy.”
“If you want to go totally ecological, it’s only sailing yacht. The reality is that today, 90 % of the market is powerboats, echoes Luca Bassani Antivari. Our aim is to reduce diesel consumption per year and per yacht: 20 to 30 % for propulsion and 40 to 50 % for generation.”

Thanks to its specific hull, WHY 58×38 requires less power at cruising speed than a boat of equal size. Its diesel-electric propulsion is the most efficient motorisation today, and the surface of the photovoltaic panels, almost 900 square metres, covers most of the boat’s auxiliary system needs.

WHY Research and Development plan to optimize this project’s energy consumption by improving the isolation of the yacht and the heat recovery of its engines, and is also investigating the latest wind energy production and wind propulsion system technologies.

In comparison to a yacht of the same size, WHY 58×38 has been conceived to reduce drastically its energy consumption, saving up to 200 tons of diesel per year.
The WHY R & D program includes tank testing for hull stability in the SSPA facilities in Sweden, and the construction of a full-scale mock-up in order to allow the design team to fine tune the living areas correctly in accordance with the hull’s unique shape.

“The WHY 58X38 yacht looks very unfamiliar but it remains on a human scale. Space is the greatest luxury on the sea, but I believe the new luxury will be the time to enjoy it”, concludes Pierre-Alexis Dumas.

Designer : Pierre-Alexis Dumas, Luca Bassani Antivari, Gabriele Pezzini, and MauroSculli

Interview with Nico :

What was the inspiration for your concept?
The inspiration was the experimental approach to molecular cooking. Even after several decades of molecular cuisine, it still seems to be an exclusive game for specialists. So it became my main goal to bring some of the fantastic possibilities and ideas of molecular cooking to all ambitious cooks with an easy to use, affordable appliance.

How does your concept fit into this year’s competition theme “Designs for the next 90 years”?
I think the idea of molecular cooking is forward-looking, but the procedures and methods of preparing molecular dishes are still conventional. I would like to change this with my concept. At first, the idea of printing food seems to be something straight out of a science-fiction movie, but on second thought it is not unrealistic at all. I even think that Moléculaire could be the future kitchen tool that opens up possibilities for food-makers interested in molecular cooking.

What are the main consumer benefits of your concept?
Moléculaire is a futuristic kitchen appliance that offers several new possibilities to professional chefs as well as home users. It’s based on a layer-by-layer printing technique that arranges small particles from a set of ingredients. Within minutes, it prints out three-dimensional desserts, complex structures, shapes for molecular dishes, and patterns for decorating a meal. In addition, it’s easy to use. You simply insert a blister pack into the reservoir, place Moléculaire on top of a plate, and press the start button. Users can also create their own recipes with special software and their own ingredients. Ambitious users can download recipes and share them with other users in an online community.

Describe the consumer research behind your concept.
I conducted interviews with chefs and did a lot of research on the Internet. These approaches helped me to understand users’ interests, concerns, wishes, needs and desires. The outcome shaped my initial ideas and helped them grow. The most difficult thing about designing for the future is predicting the possible social and technological developments (their direction and speed). Therefore, it was very useful to read reports like sociological studies about cooking and future scenarios about the development of new technologies.

What kind of materials would you use to build your concept?
For my concept, I would use polycarbonate as the main material. I plan on applying this material in three different variations, each providing the right characteristics for the different parts of my design. Transparent polycarbonate can be used for the window, black tinted for the lid/display, and white for the body. The robotic printer arm and head could be made from aluminum. A blue (O)LED backlight accentuates the processes inside the printer.

Who is your favorite designer?
I don‘t have a favorite designer.

What are your career goals?
After I graduate in 2010, I want to gain more professional experience in a product-design company. In the long term, I want to further develop my conceptual and strategic skills and step into product-related design management.

Designer : Nico Kläber

Martin interview with Electrolux :

What was the inspiration for your concept?
In my opinion, everything I have ever seen, read and heard is my inspiration. Every experience stays somewhere inside you, and if you are lucky, it will come out at the right moment. If I look back, this particular concept was definitely inspired by the book The Naked Sun from Isaac Asimov, the R2-D2 robot from Star Wars, an egg, insects, and whatever else I see every day.

How does your concept fit into this year’s competition theme “Designs for the next 90 years”?
Ninety years is very long time. Nearly four generations will pass through, every one of them with its own dreams, desires and possibilities. One long lasting dream is to reach the stars, but before that, we will have to reach Mars to see whether or not we can live without Earth. This is the time where my concept is relevant. At that time, we won’t think of machines as dumb boxes with buttons, but more as partners that obey our commands, but still have their own minds. They will be more autonomous and think and make decisions on their own. It may sound frightening, but it isn’t scarier than the first arrival of trains to the cities.

What are the main consumer benefits of your concept?
One thing you notice on Mars is the silence and serenity. That’s quite good for one week’s vacation in the countryside, but for modern people it’s very depressing to live in such a place for several months or years. Therefore, the main benefit of Le Petit Prince is that it’s not just a machine, but more like a pet or silent friend that you can speak to when you aren’t in the mood to talk to people. On top of that, it is a good gardener that grows any plant you want or need to bare life or just for its beauty.

Describe the consumer research behind your concept.
Well, I must admit it’s difficult to do any real research behind the concept since it’s designed for Mars. However, some of my friends said it’s cute (I always thought some of them have to be from Mars) and I consider their feedback sufficient.

What kind of materials would you use to build your concept?
Metallurgy, glass production and synthetic plastics have been used for a long time and will probably continue to be used in the next hundred years, so I didn’t feel an urge to use new yet unknown materials. Nanotechnology made giant leaps in the last few years and it will improve properties of material surfaces in the future, so they will be even harder and more resistant than anything we know today. More effective (even transparent) are solar panels, etc., but this evolution will not affect the fundamentals of my concept.

Designer : Martin Miklica

The executive director of the spaceport Steve Landeene said “Its real and you are definitely not talking about drawn things on paper anymore.” The spaceport is envisioned to work as an airport with different routes where aerospace companies will lease building and hanger space. Spaceport America is not just about space tourism, additionally, it will also include other business ventures like communication projects and medical research. According to the state officials, the site will facilitate around 500 construction jobs and will spark the economic development, tourism and education for generations. The runway of the project is estimated to finish next summer and the hanger and terminal should be prepared for tenants during the end of 2010.

Designer : URS/Foster + Partners

[Press Release]

DRAGONFLY, A METABOLIC FARM FOR URBAN AGRICULTURE

2009 : 800 MILLION OF URBAN FARMERS FOR RESPONSIBLE ECO-CITIES

The world of fast-food and frozen food is over! The urban keen interest of the beginning of our Century turns toward the garden flat bringing back the countryside in our overcrowded cities fighting from now on for a community urban agriculture able to contribute to the durability of the city and to rethink the food production.

On the roofs, terraces, balconies, in the hollow of the non-built public spaces, in the interior yards and the suspended greenhouses, the eco-warrior aspires to escape from its competitive and consumeristic universe imposed by the laws of the market. He desires to cultivate its immediate landscape so as to better take root in the ground by creating his own ecologic and alimentary biodiversity. The consumer becomes from then on producer and the garden inhabitant !

From the Parisian « worker gardens » to the « community gardens » of New York going though Muscovite « vegetable squares », eight hundred million of urban farmers, i.e. more than one human being out of ten, consume nowadays chlorophyllous products from these cosmopolitan kitchen gardens. These new gardens, aware of the emergency to reduce our fuel consumption and the necessity to modify our behaviour facing the climatic changes, decrease thus their environmental impact and build eco-responsible cities on a community way.

2025 : 5.5 BILLION OF CITY SLICKERS FACING THE FOOD CHALLENGE OF THE 21ST CENTURY

According to the PNUD (Programme of the United Nations for the Development), the worldwide urban population will go from 3.1 billion of inhabitants in 2009 up to 5.5 billion of inhabitants within 2025. Looking for a positive energetic assessment, the contemporary city aims within fifteen years at producing cleanly and intensively more energy than it consumes so as to pack this urban exodus! It develops therefore the urban agriculture to become food self-sufficient by recycling at the same time its liquid waste by phyto-purification, its solid waste in fertilizers by composting and by producing energy by biomass, photovoltaic cells and other renewable energies (thermic solar, photovoltaic solar, wind, tide-turbine energies…).

In order to avoid the asphixiation of the planet and the feeding of its 9 billion of inhabitants within 2050, it deals thus with reinventing the traditional energetic pattern between the city and the countryside between western countries, emerging countries and developing countries. This sums up as following: on the one hand import of natural and food resources, and on the other hand export of waste and pollution. The ecologic city aims at reintegrating the farming function on the urban scale by emphasizing the role of the urban agriculture in the use and the reuse of natural resources and biodegradable waste so as to close the loop of ecologic flows.

The urban agriculture can feed the city without any pesticide or chemical fungicide (whose toxicity is proved on the human being : cancer, sterility…), and make it less food dependant of its backcountry or other regions of the world. Organising the distribution of fresh products in short circuits, that means linked directly with the consumer, the urban agriculture complete thus the traditional agriculture. In addition to the nutritive quality of the produced and consumed food, the urban agriculture is also a growth lever of the urban unemployment market and the local economy. It is used directly as a social link in the conciliation of the primary needs of the newcomers with the challenge of their integration in the life of the city, fighting thus against poverty and exclusion. On the sanitary level, this farm approach presents also an interesting potential for the decontamination of polluted grounds and undergrounds as well as for he purification of the polluted atmosphere in CO2.

Due to the fuel crisis and climatical change, the rural agriculture of the western countries must answer to the worldwide food crisis of the developing countries and mainly Africa. Its role is from now on to produce (with an increase estimated of 60% within 2050) all the foodstuffs transportable by boat such as cereals or corn. This is based on the evolution of the science and the most advanced biotechnologies. In addition to this nutritious role, the rural agriculture is newly challenged to recycle its own culture rebus for the green chemistry in order to produce the bio fuel called “second generation fuel” using the energy of non-consumable materials from the plants, that means fibres such as celluloses.

DRAGONFLY, A NOURISHING VERTICALY CULTIVATED CENTRAL PARK

The architecture has to be in the service of this new agriculture and to design this new social desire in this context of ecologic mutation and food autonomy! The Dragonfly project suggests therefore building a prototype of urban farm offering around a mixed programme of housing, offices and laboratories in ecological engineering, farming spaces which are vertically laid out in several floors and partly cultivated by its own inhabitants. This vertical farm sets up all the sustainable applications in organic agriculture based on the intensive production varied according to the rhythm of the seasons. This nourishing agriculture is furthermore in favour of the reuse of biodegradable waste and the keeping of energy and renewable resources for a planning of ecosystemic densification.

Floor by floor, the tower superposes not only stock farming ensuring the production of meat, milk, poultry and eggs but also farming grounds, true biological reactors continuously regenerated with organic humus. It diversifies the cultivated varieties to avoid the washing of stratums of soft substratum. Thus, the cultures succeed one another vertically according to their agronomical ability to provide some elements of the ground between the essences that are sowed and harvested. The tower, true living organism, becomes thus metabolic and self-sufficient in water, energy, and bio-fertilizing. Nothing is lost; everything is recyclable to a continuous auto-feeding!

A BIONIC AND ENERGETICALLY SELF-SUFFICIENT ARCHITECTURE
The architecture of Dragonfly prototype suggests reinventing the vertical building (that outlined the urbanistic booming of New York City since the 19th Century) as structurally and functionally as ecologically and energetically.

To ensure the social diversity and a permanent life cycle (24h/24) in the tower, the mixed programmation is mainly laid out around two poles of housing and work places. Around housings, offices and research laboratories as well as the most private to the most public agricultural and leisure spaces are designed in gardens, kitchen gardens, orchards, meadows, rice fields, farms and suspended fields. The distribution of flows is made around a true safe spine spreading in loop the numerous elevators, the goods elevators and stair wells serving all the levels by separating simultaneously the inputs and the outputs recycled from plants, animals and human beings.

Architecturally, the functional organisation is represented by two oblong towers symetrically arranged in pair around a huge climatic greenhouse that links them and deploys itself between two crystalline wings. These very light wings in glass and steel retake the loads of the building and are directly inspired from the structure of the dragonfly wings coming from the family of “Odonata Anisoptera” whose transparent membrane is very finely nervured. Two inhabited rings buttress around these wings. Their organically chiselled exo-structure accommodates the inter-climatic spaces that receive the agrarian cultures. They buttress.

The whole set forms «double layer» architecture in bee nest mesh that exploits the solar passive energy at its maximum level, by accumulating the warm air in the winter in the thickness of the exo-structure, and by cooling the atmosphere by natural ventilation and by evapo-perpiration of the plants in the summer. Protecting thus the cultures from climatic changes in New York (from -25.5°C in the winter to +41°C in the summer), these plug spaces are useful to reflect on the agriculture not anymore in terms of surface area but really in terms of volume. Actually, whereas grounds nourish orchards, each wall and each ceiling are metamorphosed into three-dimensional kitchen gardens. The interior frontages of the housing and offices throw towards the skyline of New York the cantilever of their hydrophonic balconies with hexagonal section thanks to what it multiplies the culture layers by floors. The vegetation abounds, the earth is swarming of insects and animals are freely brought up in holding tanks by urban consumers with low income. The architecture becomes eatable!

Designer : Vincent Callebaut Architect

Text from Niko and Georg :
Aulis Harvester – “Development of a ground protecting forest machine”

The purpose of our creation is the sustainable treatment of the forest ground and the wood, as well as the optimization of the work sequences of the user. The base of our concept is the analysis of the work flow of the service provider with the harvester, as well as the analysis of the work flow of the farmer with the forest tractor.

With this Knowledge we could develop features in the vehicle which contribute to the optimization of the work process and guarantee a lasting protecting treatment of the forest ground.

Designer : Niko Kugler and Georg Heitzmann

Text from David:
Transportation is a key factor in our urban environments and most of our cities are now developed to match the scale and needs of cars, and car users. This reality raises issues regarding sustainability and environment, energy consumption and quality of life.

So, “How can public and personal transports be redefined in a sustainable way, delivering a sense of personal space and independence to its users?” This was the title of my Master of Science in Design and Transport Thesis, concluded in Coventry University, UK, with Distinction, in September 2008.

In other words, the aim of this project was to develop guidelines and a holistic solution for a new system of urban transport, composed of vehicle and infrastructure, in a sustainable way and adaptable to various urban environments.

To develop the project I needed information about: user’s behaviors and explanations for them; main trends; analysis of existing solutions and identification of their problems; definition of applicable technologies in a sustainable manner in a near future. This information was gathered through an online questionnaire, statistical data from several sources, literary research, internet articles, pictures, video and expert interviews and then compiled in my final report.

Preliminary research indicated that several attempts to tackle the issue of mass transportation are being tested and implemented throughout the biggest cities on Earth. Several solutions exist already, but people always seem to give preference to a personal vehicle of some kind to move, commute or make quick trips. Only when there is no other choice, people seem to engage in public transportation. Personal transport is the preferred mode of use and this is a trend that keeps increasing.

The conclusion of the thesis report was composed of guidelines and design specifications that served as basis for the development of a new type of transportation that is truly sustainable and that meets people’s requirements. This generic solution was exemplified through a typical design project that will act as future reference and that goes by the name of “SCARAB”.

PROJECT DESCRIPTION:
VEHICLE:
- The vehicle allows users to have freedom of use much like a motorcycle but with the convenience of having an enclosed private space and luggage compartments.
- The vehicle can be operated in several different positions depending on speed. It is parked vertically for easy ingress and egress and optimization of public space. When in speed position, the vehicle also tilts when curving or changing direction.
- When circulating in dedicated pathways, the SCARAB is controlled by a centralized computer or by a traffic management centre. Outside of the dedicated pathways the SCARAB is controlled by the user just like any other vehicle.

VEHICLE SPECS:
-The vehicle is composed of interchangeable modules that can be customized by the potential buyer/user.
-Powerpack module composed of a permanent battery plus 3 options for the main energy pack (battery, biofuel ICE or a fuel cell).
-4 wheel drive through electric brushless in-wheel motors with directdrive.
-Wheels with regenerative braking through EW Brakes.
-Drive by wire and tactile HUD embedded in the Lexan canopy.
-Structural elements in Carbon-Aramid composite.
-Embedded sensors, Lidar, radar, transponders, GPS. These serve to exchange information with the system, with other drivers and to have precise location data.

INFRASTRUCTURE:
-Communication nodes spread through roadways and traffic management centres in major conurbations.
-Dedicated paths with electromagnetic transponders embedded in the road.
-Parking facilities with solar/wind power generators.
-High speed/long distance travel provided through a railroad interface (not yet developed).

SYSTEM:
-Renting of the vehicle or modules that allows for a private/public/mixed utilization and transport access for people with less financial resources.
-Doesn’t need new infrastructures (uses the existing roads).
-Is backward compatible with current transport systems and uses current day technologies.

Designer : David Miguel Moreira Gonçalves

Text from Chris :
Over the last few years it has become more apparent just how susceptible our country is to the ever changing climate. Throughout each of the eastern states of Australia we have seen continual diminishing rainfalls which have in turn brought on increasing water restrictions with the thinning water storage levels. The consequences of these climate changes are only just beginning to be felt by the general public. One of these areas is grass roots level sporting communities. This research/design based project explores the challenges these sporting communities face and how certain strategies may be used to combat these climate changes. The aim of this project was to further develop water conservation strategies within the sporting environment and design a device and system that would be used in the collection and storage of rain water.

The Watree concept is for urban sporting grounds, and based around the idea that almost all of these reserves have buffer zones around them. A buffer zone is more common around ovals due to their shape, but can be found around tennis clubs and soccer pitches as well.

A buffer zone is essentially an area of land around these sporting reserves, unused. Often they are just grassed areas or areas dotted with a few unsightly shrubs, sometimes used as car parks. These buffer zones do not provide any particular use to these sporting organizations and when rain falls, its seeps straight into the ground. I propose using these buffer areas as location points for open air rain water collection.

The Watree concept is to have a number of these points around an oval, with the collection unit to be in the centre of these buffer zone areas. The idea is for these devices to open up when it rains and create a large surface area that would then collect and funnel the rain either into storage directly beneath it, or along a pipeline to a central tank storage for the ground. The water would pass through a filter accessible from outside of the Watree structure on its way to storage. This water, previously wasted, would be stored and used during summer periods to keep the sports surface in a playable condition. Combined with a playing surface converted to warm season grasses, a large storage tank would be a suitable amount of storage for weekly watering of the field over summer. In the case of a tennis club for example, smaller tanks and water collection would be required dependent on the number of grassed and clay courts.

The watering system to be utilized is KISSS (http://www.kisss.com.au/). KISSS has been developed, and is manufactured by, an Australian company called Irrigation & Water Technologies Pty Ltd (IWT) at Rouse Hill, NSW. There are parts of the project still to be refined as well as the development of a community water donation system. Currently I’m assessing the project and the possibility of Government grants from the Smart Water Fund (http://www.smartwaterfund.com.au) for further development.

Designer : Chris Buerckner

[Press Release]
Honda FC Sport Design Study Suggests Hydrogen Sports Car Future

LOS ANGELES, Nov. 19, 2008 – Honda today revealed the Honda FC Sport design study model, a hydrogen-powered, three-seat sports car concept, at the 2008 Los Angeles Auto Show.

The FC Sport emphasizes the design flexibility and potential of Honda’s V Flow fuel cell technology – already deployed in the Honda FCX Clarity sedan – and reconfigures it into a lightweight sports car design with an ultra-low center of gravity, powerful electric motor performance and zero-emissions. The design study concept is inspired by supercar levels of performance through low weight and a high-performance, electrically driven fuel cell powertrain.

“The Honda FC Sport explores how to satisfy automotive performance enthusiasts in a world beyond petroleum,” said Dan Bonawitz, vice president of American Honda Motor Co., Inc. “People who love sports cars will still have a reason to love in a hydrogen-powered future.”

The high-output Honda fuel cell powertrain and a sleek, aerodynamic body contribute to the vehicle’s performance potential. A modular approach to fuel cell component packaging and the electric drivetrain contribute to the FC Sport’s low center of gravity with the majority of vehicle mass distributed between the axles, creating the balanced weight distribution sought after in sports cars.

The ideal placement of the Honda V-Flow fuel cell stack and related components demonstrates the benefits of a platform-specific, hydrogen-powered fuel cell powertrain. The FC Sport is configured to accommodate a custom-formed high-power fuel cell stack, located between the rear seats, and a battery pack placed low in the middle of the vehicle. The electric motor resides just forward of the rear axle. Two fuel storage tanks, visible from above, are located above the rear axle.

The optimal placement of fuel cell components for performance also allows for a relatively large passenger cabin by conventional supercar standards with enough space for three seating positions. The interior layout focuses primarily on the driver with a racecar-like center driving position. The enclosed canopy opens upward from the rear to allow for entry and exit. Two rear passenger seats flank the driver’s left and right side.

The sleek, low-profile body is designed to convey a high-technology appearance with sculpting that combines angular shapes in the front of the vehicle that taper into geometric, hex forms in the rear. The rear hex forms house cooling radiators for the fuel cell. Formula 1-style barge boards behind the front wheels enhance high speed aerodynamics and convey the vehicle’s racing pedigree. The hydrogen storage tanks, visible from the rear deck, showcase the FC Sports fuel cell technology in much the same way that a “naked bike” motorcycle showcases its engineering technology.

The glacier white body color conveys the FC Sport’s clean environmental aspirations while the dark wheels and deeply tinted glass provide a symbolic contrast befitting of the vehicle’s unique combination of clean power and high performance. Green construction techniques further contribute to a reduced carbon footprint. An organic, bio-structure theme is carried through to the body construction where exterior panels are intended to use plant-derived bio-plastics.

The Advanced Design Studio of Honda R&D Americas, in Pasadena, California, developed the FC Sport design study with the primary objective of using existing fuel cell technology as the basis for an ultimate Honda sports car. Designer Jason Wilbur led the design efforts.

Honda R&D Americas, Inc. began its operations in California in 1975 with local market research activities and has steadily grown its capabilities over the past 33 years to include all aspects of new vehicle design and development. Recent development efforts include trend-setting products such as the Honda Pilot, Ridgeline, Element, Civic Coupe and Civic Si.

In 2008, the company opened two new design centers in Southern California: the Acura Design Studio (Torrance), for the research and design of new Acura products; and the Advanced Design Studio (Pasadena), for the exploration and development of advanced design themes for both Honda and Acura.

The company operates 11 major R&D facilities in North America, including a full vehicle development center in Raymond, Ohio, and three design studios in Southern California. Honda R&D designers, engineers and support personnel are engaged in the development of Honda and Acura automobiles, powersports products, and power equipment for North America and global markets. The company’s main centers of operation include the Los Angeles Center (Torrance, California), responsible for market research, concept development and styling design; the Ohio Center (Raymond, Ohio), responsible for complete product development, testing, and support of North American supplier and manufacturing operations; and a dynamic test facility in Cantil, California.

NUVU: RESHAPING THE CITY

Within just a few years, cities all over the world will be at near bursting point. If mankind wants to retain the level of personal mobility it currently enjoys – and if the city is to survive – the only way forward is for a radical rethink of the type of cars driven there. One solution could be a car like Nuvu, designed for the city of the not-too-distant future.

“Nuvu is literally a ‘new view’ at the future of the city car. It is electric, of course, but as far as Nissan is concerned, for tomorrow’s city cars that is a given. No, the most important aspect of Nuvu is the interior design which provides great comfort and space in an intelligent package designed to make best use of our crowded roads and limited parking slots.”

François Bancon, General Manager, Exploratory and Advance Planning Department, Product Strategy and Product Planning Division, Nissan Motor Co., Ltd.

At a glance

- 2 +1 seating in compact 3m package
- Unique platform for Nuvu
- Zero emissions from EV drivetrain
- Drivetrain previews production EV due soon
- X-By-Wire control for all dynamic functions
- Extensive use of natural, organic and recycled materials
- An urban oasis complete with its own tree inside, which…
… provides shade for the interior, and
… generates solar energy via its ‘leaves’

Overview
There is about to be a seismic shift in the urban landscape. Within the next five to seven years, some 55 percent of the world’s population will live in the city, threatening total gridlock. Unless something is done, the irony of the phrase ‘personal mobility’ will be self-evident.

Look around at the cars in a typical city traffic jam today and the vast majority will have only one occupant and four empty seats. Some might have two occupants, a few three. But find one with four occupants or more and you’ll be doing very well.

Today, we buy a family car knowing that we’ll only ever need to use it to its full potential one or perhaps two percent of the time. Tomorrow, things will be different. Tomorrow, things have to be different.

“There is a new generation coming up who, finally, are questioning why we do the things we do. They are asking themselves, for example, why they are buying a large car when they know that for 99 percent of the time they will be in it on their own,” says François Bancon, General Manager, Exploratory and Advance Planning Department, Product Strategy and Product Planning Division, Nissan Motor Co., Ltd.

“It is our job to provide personal transportation that is better suited to people’s needs and to what the environment – in all senses – can cope with.”

Nissan’s vision for the future of urban transportation is encapsulated in Nuvu, a ‘new view’ of the type of car we will be driving in the middle of the next decade. Compact – it’s just 3 metres long – Nuvu is a concept vehicle with unique 2+1 seating. It is aimed at urban dwellers who don’t want to compromise on their personal freedom or their comfort, yet who appreciate that ‘something has to give.’

Nuvu is agile, easy to drive, even easier to park. And it is, of course, an electric vehicle (EV). As Bancon says: “We believe zero emission vehicles are one of the key solutions for tomorrow’s city car.”

Nuvu is described as a moving oasis, a haven of green tranquillity in the urban jungle. To underline this message, Nuvu incorporates a witty representation of its green credentials: across its all-glass roof are a dozen or so small solar panels. Shaped like leaves on a branch, the power they generate is fed to the battery using a ‘tree trunk’ within the car as a conduit. Nuvu also uses natural, organic and recycled materials within the cabin.

Nissan has already announced plans to introduce an all-electric car in Japan and the US in 2010 and to mass-market it globally in 2012. Nuvu is not that car, though it does share some of the technology that will feature in the planned production vehicle. Rather, it is a concept of how a Nissan EV might look in the near future.

In the longer term, Nissan foresees a future based around a line-up of zero emission vehicles regardless of their size, category and usage. Nuvu – or its production equivalent – is just one element of this emission-free future.

Nuvu in detail
The central thrust behind the development of Nuvu is not its motive power but its layout and use of space. Nuvu has been created for a city of the future, one that’s even more crowded than today.

That’s why it’s compact on the outside yet roomy on the inside. Built on a unique platform, it’s just 3 metres long and sits on a wheelbase of 1980 mm but is 1700 mm wide and 1550 mm tall to create a large and airy cabin.

Interior package
These dimensions provide all the interior room needed for the vast majority of city journeys. Nuvu has two regular seats and a third occasional chair that can be folded down when required. But, unlike some two-seater city cars currently on the market, it is a thoroughly practical proposition with an integral luggage area providing sufficient space for a typical supermarket or shopping expedition.

“It is a real car,” says Bancon. “There would be no disadvantages to using a Nuvu everyday. For the vast majority of users, three seats are more than enough most of the time.”

The packaging is designed to give priority to driver comfort with C-segment levels of space and the flexibility to invite one or two passengers on board. Cabin layout places the regular passenger seat beside but largely behind the driver’s seat, allowing the passenger to stretch right out. Ahead of this seat is a third occasional chair which, when not in use, is folded away into the dashboard assembly. But even when the third seat is in use, there remains sufficient legroom for both passengers.

In the interests of saving both weight and space, the third seat has a centre section made from hardwearing yet comfortable netting. This hammock-like approach also has the benefit of allowing cool or warm air to circulate around the occupant’s body for extra comfort.

Shopping bags, briefcases and smaller items of luggage can be stowed behind the driver’s seat while if the driver is travelling solo, larger items can be stowed in the passenger footwall.

City car research
“We did a great deal of research into how people use their cars in the city. We found that for 90 percent of the time, the driver was alone. For five percent of the time there was one passenger and for four percent of the time there were two passengers. You can do the math to find out how often four or more people were in the car!” says Bancon.

“We gave the second seat much more room than normal because when you take one passenger in your car it is usually someone you love and you want to make sure he or she is being carried in outstanding comfort,” he adds.

Natural materials
Many of the materials used inside Nuvu reflect an increasing concern for the environment. The floor is made from wood fibres pressed into laminate sheets and is studded with rubber inserts made from recycled tyres for grip.

To create a light and bright interior, the windscreen and roof merge into one extended panel running virtually the entire length of the car. But undoubtedly the most unusual feature of the interior is the ‘energy tree’ which rises from the luggage compartment floor to the roof behind the driver’s seat.

Solar panels
The energy tree is shaped like a thin trunk. As it reaches daylight it branches out under the glass roof providing occupants with protection from bright sunlight… just like a real tree. And providing a visual reminder of Nuvu’s green credentials, covering the branches are dozens of small solar panels shaped like leaves.

The panels absorb energy from the sun which is then fed back down the energy tree and used to help recharge the battery and provide an extra power boost for the electric motor. As well as being genuinely green energy, it is estimated that the power generated via the solar panels will save the equivalent of one full overnight charge from mains electricity each month.

Driver controls are as simple as possible. All the major functions – steering, braking, transmission and throttle – are ‘By-Wire’ while the steering is controlled by an aircraft-style steering yoke: with just one turn from lock to lock, the steering is very direct for agility and manoeuvrability in the city. Nuvu’s turning circle is just 3.7 metres. Thanks to its wide track and the use of 16 inch 165/55 tyres mounted on lightweight, almost transparent, wheels, ride comfort, stability and agility is of the highest order.

There are two pedals – for stop and go – stalks for minor controls and a digital instrument panel with dials for speed, distance covered and battery range. The instrument panel itself is formed of layers – rather like an onion – and like the energy tree is another example of design inspired by nature. “We call it bio-mimicry,” says Bancon.

Rear view/parking monitor
Two screens on the dashboard display the view behind the car – there are no door mirrors to disturb the airflow, but small cameras – and double as monitors for the Around View Camera which give a bird’s eye view of the car when manoeuvering or parking.

Saving energy was the guiding force behind the use of low-energy LED head and tail lamps, while Nuvu’s heating and ventilation system filters and cleans the city air as it passes through the vehicle. Not only does it produce no emissions at source, but Nuvu actually helps clean up the city environment.

Exterior and interior design
“Nuvu’s design is further clear evidence of Nissan’s continued desire to challenge convention and to explore all the possibilities that the EV could bring us. In many ways it was inspired by our two most extreme EVs of recent times: Mixim and Pivo 2.

“Significantly, though, Nuvu delivers a more realistic interpretation of two of the most important aspects of its forerunners – the ‘Friendly Innovation’ found in Pivo 2 and the ‘Sports Dynamics’ central to Mixim

“The result? We have designed a radical concept car that with just a few changes could go into production tomorrow,” explains Masato Inoue, Chief Designer, Product Design Department, Nissan Motor Co., Ltd.

Developed by designers at Creative Box Inc. – Nissan’s design think-tank – Nuvu’s green house has flowing lines with gentle curves inspired by nature. The distinctive shape of the door glass on either side gives the impression of a hot air balloon that’s being gently inflated by pressure from within, while tropical fish inspired the profile of the side window graphics as a whole.

This contrast between the natural, fluid shape of the greenhouse and the strength implied by the solidity of the lower body gives Nuvu a feeling of quality rarely found in a compact car.

Colour and materials
Nuvu’s visual impact is further enhanced by its unique body colour. Developed by Nissan Design, the shade is officially called Soft Feel Sandy Gold.

Matching the ecological values of an electric vehicle, the moulded plastics and synthetic elements found inside a typical production car have been replaced by natural materials and organic alternatives, such as the wood fibres and rubber from car tyres used for the flooring. The result helps create a relaxed, warm atmosphere within Nuvu’s cabin.

During the design development stage, key targets were to develop an EV that encompassed obvious modernity with engaging ambience and a playful aspect – hence the energy tree. “You don’t need to be a car lover to fall in love with Nuvu,” adds Bancon.

EV drivetrain
Nuvu is more than a styling concept of a future EV. It is a fully working mobile test bed for much of the technology that will be used in Nissan’s production EV to be launched in 2010. For this reason elements of its technical specification are being kept secret for the time being.

The electric motor used in Nuvu is mounted at the rear of the vehicle and drives the back wheels, though neither its exact specification nor the power and torque figures are being released at this stage. A driving range of 125 kms and top speed of 120 km/h are being made public, however.

Li-Ion battery
Similarly although it can be revealed that the batteries used are of the latest laminated lithium-ion type and have a capacity of 140 Wh/kg (watt-hours per kilogram), the total capacity of the batteries and number of modules are not being disclosed at this stage.

Nissan began research into high output Li-Ion cells as long ago as 1992, but today development is carried out by Automotive Energy Supply Corp. (AESC), a joint venture company set up by Nissan and NEC Group.

Unlike a conventional lithium-ion battery with its bulky cylindrical cells, the laminated Li-Ion battery as used in Nuvu has thin laminated cells and fewer components overall. This boosts its power by a factor of 1.5 at the same time as halving its physical size. It also remains twice as efficient as a conventional cylindrical Li-Ion battery even after five years or 100,000 kms of continuous usage.

Another bonus of the compact cell construction is that a thin modular design is possible with a commensurate improvement in battery cooling efficiency. Higher power outputs are achieved through material improvements made to its lithium manganate positive electrode and carbon negative electrode. The use of chemically stable spinal-structured manganese for the positive electrode also helps ensure safe operation.

Its compact size allows the batteries to be mounted under the seats and the vehicle’s flat floor, thus helping to keep the centre of gravity as low as possible.

A quick charge from empty to full should take between 10 to 20 minutes while a full charge should take between three to four hours from a domestic 220V socket.

Typical users
“The people who will be drawn to a car like Nuvu are many and varied,” says Bancon. “It is a cross generational car and not a signature vehicle for one generation.

“There will be common threads, however. They will be early adopters but more importantly they regard themselves as urban citizens. They don’t just work or live in the city; they are part of the city. They want a car that somehow expresses who they are and which reflects their personal ideology.”

Conclusion
Although clearly a concept vehicle exploring aspects of future vehicle design, Nuvu nevertheless embodies many messages for today. Its clever interior provides ample headroom, legroom and comfort for most everyday needs without occupying more road space than it needs.

The use of recycled and natural materials underlines Nuvu’s environmental message and while the energy tree might be considered as a piece of whimsy, the use of solar energy is an entirely sensible and practical technological solution to aid an emission free future.

“Nuvu is a concept car, for sure, but it is an entirely credible vehicle,” says Bancon. “It is light, clean and easy to drive. It is practical and a sensible size, yet it is also embodies an element of fun: the future doesn’t look so bad, after all.”

Designer : Nissan