Energy Secretary Steven Chu said today that the Obama administration's budget will not contain any funding for developing hydrogen powered vehicles.
It seems that the Obama administration wants to focus on alternative energy technology that can be developed quickly. Right now, plug-in hybrids and all-electric vehicles right winning the popularity contest.
Both technologies, however, have serious infrastructure issues that must be address before we will see a national wide adoption.
The main barriers to plug-in hybrids and all-electric vehicles are the production of lithium batteries, recharging time, recharging stations, and the vehicle range.
The main barriers to hydrogen powered vehicle are the production of hydrogen and fuel cells, the distribution of hydrogen, and the on board vehicular storage of hydrogen (300 mile range).
For MS, I worked at Lawrence Livermore National Laboratory (LLNL) to design and test hydrogen storage technologies.
The team created a cryogenic capable pressure vessel (CCPV) that can store 10.7 kg of liquid hydrogen. This system was tested in a Toyota Prius in January 2007 and it achieved a 653 mile range.
Lets not forget that both technologies are just passing the buck when it coming to emissions.
Most of the hydrogen produced in the United States is made from the steam reformation of natural gas (methane). Currently, ~ 49% of the electricity produced in the US comes from coal-fired plants.
While I agree that it is probably easier and less costly to set up the infrastructure for plug-in hybrids and all-electric vehicles, I still do not believe this is the best way forward.
Right now, the Telsa Roadster can travel 244 miles (393 km) without external loads on the battery, i.e. no A/C running, no radio turned on, no phone or Ipod charging,...... You get the picture.
Furthermore, it takes 3.5 hours to fully recharge the Roadster. When I think about the usage phase of a car, electric vehicles just don't appeal to me. The recharge time is too long for my preferences and I am unsure about the actual range of these vehicle under "normal" stop and go driving conditions.
The system design at LLNL was flexibly refuelable. The CCPV can store compressed hydrogen gas at room temperature, compressed hydrogen gas at 80 degrees K (all gases occupy less volume at colder temperatures), and liquid hydrogen (LH2) at 20.28 K.
This allows a user to decide which fuel type they need based off of driving requirements and cost. If users wanted to travel short distances (~120 miles), they could choose hydrogen at room temperature. This is the cheapest to produce, but you store less hydrogen in the system.
If users wanted to travel further than 300 miles, they choose LH2. It is the most expensive to produce but you store more in the system for extended ranges: ~300 to ~500 miles. The refuel system is similar to the current gasoline system and can be completed under 5 minutes.
I would be a raging supporter of electric vehicles if (1) the electricity comes form renewable energy sources, (2) the recharging time was reduced to at least 30 mins, and (3) the range is equal to that of an internal combustion engine (300 miles or more).
Right now, I am for continuing development of both technologies and letting the range, cost, and emissions performance decide the winner.
|
AuthorI am just a Southern gentleman at UC Berkeley that wants to enable people to live better and be productive citizens. Archives
December 2013
Categories
All
|