No plug? No Problem. MIRA Debuts the "Plugless Plug-In Hybrid"
Filed under: Emerging Technologies, EV/Plug-in, Hybrid, UK
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What in the world is a plugless plug-in? That's the question we were asking ourselves as we read over the press release pasted after the break. It seems that MIRA, a design, development & certification consultancy in the UK, has created three removable battery packs which fit in the trunk of a car and can be removed separately for recharging. This scheme has a few benefits, especially for those individuals who do not have access to an outlet where they park, as the batteries can be moved to a better location. Also, those batteries could be used in other applications, for instance as power when you're camping or for other outdoor applications like quads or electric bikes.
MIRA calls its system H4V, which stands for "Hybrid 4wd Vehicle," and it uses lithium ion phosphate batteries. The current test-bed is a Skoda Fabia, which normally returns 39 mpg in the combined cycle. After the H4V system was added, the vehicle was able to attain 64 mpg on the same driving loop, which represents a 61 percent improvement. Equally as important, tailpipe emissions were reportedly reduced 39 percent. MIRA projects a price of approximately £2000 for a retrofit H4V system.
Press Release:
MIRA Debuts "Plugless Plug-In Hybrid"
Automotive designers MIRA have unveiled a retro-fit hybrid conversion that unlocks the potential to save 61% on fuel costs and lower tailpipe emissions by 39% without designing a new car. The hybrid conversion with a novel removable battery pack upgrades existing vehicles to the technology some concept cars are showcasing at this year's motor shows. A technology demonstrator has been built around a popular b-segment car to show the potential of the technology. As a "plug-in hybrid" the vehicle can charge its batteries by running its engine or by plugging into the mains. Plug-in hybrids are at the vanguard of new vehicle design; yet MIRA has taken the idea one step further to make the concept far more practical and useful for motorists.
As a concept evaluation tool the Hybrid 4 wheel drive Vehicle (H4V) was never destined for public sale, so the project received support through the Energy Saving Trust's Low Carbon R&D programme which is funded by the Department for Transport.
Philip Sellwood, Chief Executive of the Energy Saving Trust, which is managing the initiative said: "This project has designed a new system allowing hybrids to be more flexible and practical for every day use. With over 20% of the UK's total carbon emission produced by road transport every year, these advances in technology are vital. Over 80% of people believe that climate change is having an impact on the UK right now, so it is important to bring more technology like these to the market place."
Commenting on the new design Transport Minister Jim Fitzpatrick said: "With the challenges of climate change, we need to find opportunities to contribute positively to protecting our environment. Working with the Energy Saving Trust has been just such an opportunity, and I'm delighted that funding from the DfT's Low Carbon R&D programme has been put to good use in developing an efficient petrol hybrid car.
Road transport is key in our efforts to cut carbon, and bringing cleaner vehicles on to the market is vital to achieving this goal. I understand that MIRA have comfortably exceeded their emission target after tests, which is a really encouraging result, and I look forward to hearing more good news about the programme."
Derek Charters, MIRA's Advanced Powertrain Manager explains the rationale behind the project: "Despite advances in powertrain technology you can still obtain electricity from your domestic provider far cheaper and greener than you can produce it via an automotive combustion engine, so 'plug-in' hybrids make sense. With this project we've removed the primary limitation of the 'plug-in hybrid' concept by allowing the battery pack to come to the mains, rather than having to park right next to a socket ...which is more than a little difficult if you live in a terraced house or flat."
The H4V project was conceived to show just what's possible with a regular car and some specialist knowledge. Derek explains further: "MIRA's hybrid vision is to lower tailpipe emissions and deliver better fuel efficiency than an equivalent diesel, at a diesel level 'on-cost'; whilst delivering driver delight features such as an EV mode and "two-pedal" town driving."
This is precisely what MIRA have done with H4V. The demonstrator vehicle is based on the popular Skoda Fabia, instantly differentiating itself from the standard model by the unique H4V badge and aerodynamic modifications. The 50/50 hybrid derives power jointly from a 60Kw petrol engine at the front and two 35KW inboard motors powering the rear wheels though MIRA's clever e-differential. Overall, the H4V differentiates itself from the standard model by returning 64mpg2, as measured on the EU drive cycle. Whilst general levels of performance, such as top speed and acceleration are similar to standard.
The car boasts a battery pack arranged into 3 portable cassettes, each capable of storing 30KW. These storage units could also power external devices, including a range of lifestyle accessory items. The very latest nano-particle technology has been applied to increase the energy density of the already 'high-tech' Lithium Ion Phosphate batteries. This ensures the energy pack is as lightweight and compact as possible, whilst delivering superior voltage stability over the charge range. The same Li-Ion Phosphate battery technology is evident in the separate low voltage circuit used to start the engine, insuring the car's impeccable 'lead free' green credentials.
The battery pack in one of the key ingredients of a modern hybrid. With so much effort and expense being invested in the battery pack it makes sense to use it in as many places as possible, not just the car itself. The ultimate aim of the project team is to see the power pack transferred from the car into a range of other devices, which could include camping equipment for SUV variants, or redeployed to power electric jet skis or quad bikes.
Despite the impressively green credentials, headline grabbing hyper-economic mpg figures were never the aim for H4V - to do that the team would logically select a more frugal base vehicle. The selection of the base car is largely unimportant, as far as the technology is concerned; so long as the donor vehicle's specification included modern features, such as a throttle by-wire system and some other basics, to avoid duplicating unnecessary workload. The project code of H4V, standing simply for 'a' Hybrid 4wd Vehicle re-enforces the generic nature of the upgrade.
A 39% improvement is beyond what most traditional hybridisation systems would normally deliver, so MIRA have retuned the engine and created a custom calibration that works in harmony with the electrically driven axel to deliver additional synergies beyond the simple fuel savings possible via 'torque-neutral' hybridisation schemes.
A regenerative braking system makes its debut on a MIRA hybrid. Derek explains why: "The viability of such systems requires careful analysis to ensure that the mass penalty is outweighed by the energy recovery potential. The technology has now matured to deliver a tangible economy benefit, not just a 'feature' for the marketers."
The frugal powertrain is supported by a new aero pack, further reducing drag by 8% to achieve a Cd of just 0.299. Aerodynamics makes only a small contribution to EU drive cycle calculations, due to the cycle's overall low speed character, so it's often marginalised by those wishing to bias development towards attributes that make the most difference at low speed. Thankfully, MIRA's approach goes some way to deliver a vehicle that lives up to consumer expectations on real roads.
[Source: MIRA]
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Reader Comments (Page 1 of 1)
4-24-2008 @ 3:30PM
ClayW said...
That article states that "MIRA projects a price of approximately £2000 for a retrofit H4V system." Surely this doesn't mean a retrofit of a standard gasoline combustion engine to a hybrid-electric? It must mean retrofitting an existing hybrid with the new battery system? Can anyone confirm this for me? Thank you!
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4-24-2008 @ 4:24PM
eddy said...
Nope. £2000 has to be the complete system.
The Fabia isn't a hybrid by design. So this guys have added the complete hybrid system. Seems to be similar to the Bosch transmission-integrated parallel hybrid. The Bosch system has similar costs (2000-3000 €). But this one seems to be more advanced, because it is a Plug-In-Hybrid.
I think it would be a good thing for Volkswagen/Skoda to buy this system and to sell it in the Skoda Fabia/Seat Ibiza/Skoda Roomster and VW Polo.
9900 € for a Fabia + 3000 € for the Hybrid System =
A small hybrid with better fuel-economy than the Prius for less money.
Reply
4-25-2008 @ 12:29AM
Wave54 said...
Something's wrong with this story, or it's just unclear. That price of £2000 ($4000) provides the conversion kit to transform a FWD car to an AWD with rear hub motors, all the controllers, on-board charger and 3 30kw battery packs? Doesn't seem likely.
You'd be hard-pressed to pay for a small lithium ion battery pack alone for that price. They can't possibly mean a capacity of 90kWh of storage in 3 portable cassettes? That exceeds the capacity of the the 900 lb. pack in the Tesla.
What am I missing?
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4-25-2008 @ 3:33AM
Chris M said...
Wave54: I also was puzzled, until I realized that they were speaking of each pack having 30 Kilowatts of Power, not 30 Killowatt-hours of Energy. A 30 Kwh battery pack would weigh over 540 lbs, and certainly couldn't be toted to the nearest outlet!
I suspect they are using high power LiIon cells, each pack with 30 Kw power but likely only 1 or 2 Kwh of energy. That would make each of the 3 battery packs somewhere between 18 to 40 lbs each, within the ability of many people to tote, though most will probably want to use a cart.
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4-25-2008 @ 4:14AM
jake said...
@Chris M
I'm not that convinced many people will want to lift a battery esp if it is 40 lbs back and forth to and from their apartments. Even if it was nearer 20lbs, and it may not be that hard, but it's definely not going to be fun, esp in areas involving stairs. But I suppose it is good exercise and the person will pretty much have to do it everyday. Another thing is that this never mentioned the capacity of the battery, which bothers me. If it was 2kWh per pack as you said, it will give 6kWh and around 30 miles of total range if they used the pack fully. And this design looks to cut into trunk space like most hybrids, while other designs can find more creative ways to stow the battery, like the Volt doing it in the center tunnel. But the price looks to be very optimistic esp if they are talking about a whole system. $4000 isn't that big of a premium for a whole plug-in conversion.
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4-25-2008 @ 6:34AM
Scatter said...
£2,000 for the whole lot is what they're aiming for. It'll take some time to get there but if they do, I suspect they will go far.
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4-25-2008 @ 1:22PM
jfb said...
Even at a putative 30-lb weight for each of the three cells, I'm not about to lug those puppies up three flights of stairs on any sort of regular basis.
So perhaps all apartment buildings in the world need to change their design to include outdoor power points. Until that happens, plug-in or even semi-plug in isn't a viable solution. Self-charging hybrids are far more attractive.
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4-25-2008 @ 4:31PM
bvz said...
The most interesting part about this story, for me, is that this is a retrofit. I'm less concerned about the removability of the batteries.
For years I've been wondering whether it would be possible for me to upgrade my front wheel drive A4 to be a plug-in hyrbrid (because of it's 4WD cousins from which I could kip parts to drive the rear wheels). Alas, it is a project too complicated for my tiny brain and limited amount of free time.
What this shows me is that, in theory, such upgrades are possible. Imagine the possibilities! If, in fact, you could upgrade your current car (well, recent enough model car) to double the gas mileage for about $4K, it would be pretty awesome. Of course, not that many people would opt for it, but as gas prices climb, and as the economy sours, $4K to cut your gas bill in half would pay back in... let's see... 5 years (assuming a 30MPG car running 12K miles per year and $4/gal gas). That would be roughly 3.3 years if you had a 20MPG car.
Ok, maybe it isn't all that compelling financially. And this is all assuming the hype of doubling your gas mileage (and not taking into account the costs of electricity)...
Ok, nevermind :) Cool idea, but maybe that's it.
sigh.
Why do I even bother?
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4-25-2008 @ 6:36PM
comatus said...
The exciting concept here is the modular battery pack. Once subscribed to the Electric Motor Assn, you could drive your limited range, pull into a station, unplug, and fit freshly-charged batteries, probably in less time than refueling a gas engine would take. Then, receive a monthly bill for wattage, and a penalty fee for passing off clapped-out batteries into the rotation. That there would be progress indeed.
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4-26-2008 @ 12:37PM
Nicholas said...
Great concept, although removeable also equals stealable. Takes me back to the 1980s when people were packing their car stereos around with little handles.
Heh!
Gradually understanding sustainable living at http://www.movinglikewater.com
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4-27-2008 @ 6:57PM
Phil said...
The concept of lifting propulsion batteries out of a car if the driver cannot park within extension cord distance of a battery charger is possible — but most drivers would not have the stamina, or the time, to do this every day.
A purpose of plug-in hybrid electric vehicles is to allow short trips to be driven on battery only. What is the battery-only range of this car?
I would like to know what electrical connectors they are using — that would allow fast and reliable connection and disconnection of battery connections on a daily basis. What is the amperage rating of the battery connections?
What is the kWh storage capacity of each of the three batteries?
What is the weight of each battery?
What is the voltage output of each battery pack?
Is the battery charging circuitry built in to each battery pack?
How long does it take to charge the batteries — and if a higher capacity wall socket is available, how is fast charging accomplished?
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