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    Vehicles has to be electricity powered but not gasoline!

    A century ago, more automobiles were powered by electricity than by gasoline.

    Invention of the lead–acid battery in 1859
    Electric-powered two-wheel cycle in 1867
    First production electric car in 1884
    Interest in motor vehicles increased greatly in the late 1890s and early 1900s.

    Parker-Edison Electric car.jpg

    But the need for longer travel ranges, the availability of a more affordable fuel source and a reliable power infrastructure soon turned internal combustion engines into the predominant means of motor transportation.

    Now drivers are considering a move away from gasoline and back to electricity as an ideal source for automotive power, but big challenges remai n. Many companies, universities and researchers are working on solving one of the biggest barriers to widespread electric vehicle adoption: limited battery range.

    Most people consider switching to electric vehicles to save money on gas and contribute to a healthier environment. But “range anxiety,” the fear of being stranded with no power, was cited by 64 percent of consumers as a main detractor to buying an electric vehicle.

    Electric cars today typically can travel only about 100-150 miles (depends on the vehicle brand and type) on current battery technology, called Lithium-Ion (Li-Ion). This technology stands little chance of being light enough to travel 500 miles on a single charge and cheap enough to be practical for a typical family car. This problem is creating a significant barrier to electric vehicle adoption.

    The-Plan - Fast charger.jpg

    Lithium ion Battery; “Range and Price Anxiety”!

    The traditional lithium-ion chemistry involves a lithium cobalt oxide cathode and a graphite anode. This yields cells with an impressive 200+ Wh/kg energy density and good power density, and 80 to 90% charge/discharge efficiency.
    However the downsides of traditional lithium-ion batteries include;
    • - Expensive (85kWh Tesla battery USD 17,000)
    • - Heavy (85kWh Tesla battery is 550kg)
    • - Short cycle lives (hundreds to a few thousand charge cycles) and
    • - Significant degradation with age.
    • - The cathode is also somewhat toxic.
    • - Also, traditional lithium-ion batteries can pose a fire safety risk if punctured or charged improperly.
    • - The 18650 type battery cells (used in laptop battery cells as well) which Tesla uses 7104 of them for the 85kWh battery, don't accept or supply charge when cold, and so heaters can be necessary in some climates to warm them.
    Most other EVs are utilizing new variations on lithium-ion chemistry that sacrifice energy and power density to provide; fire resistance, environmental friendliness, very rapid charges (as low as a few minutes), and very long lifespans. These variants; lithium iron phosphate batteries to last for at least 10+ years and 7000+ charge cycles, lithium-manganese spinel batteries to last up to 40 years and Lithium vanadium oxide for doubling energy density.

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    Li-Ion battery technology is not suitable for EVs

    Currently, Tesla uses thousands of individual Panasonic 18650 laptop battery cells in its battery packs. 7104 of those cells are used for making a 85kWh 550kg battery pack which is about USD 17,000, offers a cost of $200 kWh and energy density of 155 Wh/kg.
    Btw, I use the 18650 batteries in my torches and mobile phone battery packs as well. But they are scary dur to the fire hazard. I never leave the charger on during the night time, I switch off the charger before I go to bed.

    18650_Tesla Model S battery.jpg

    Once Tesla’s $5b Gigafactory production begins though, Tesla will be upgrading to new 20700 battery cells, which will be physically a little bit larger, capable of holding more energy, and thus requiring fewer individual modules.
    The main goal of the Tesla Gigafactory is to bring battery costs down by some 30%, allowing the Tesla Model 3 the ability to offer a 200-mile driving range for just $35,000. Still quite expensive for many people.
    Obviously there’s a lot that still needs to happen for electric cars to even be on par with their conventional counterparts.

    Tesla Stock Falls on Video of Fiery Crash
    tesla_car_burning.jpg

    “Electric Vehicle manufacturers and battery suppliers are currently investing millions of dollars into battery Research & Development aimed at obtaining greater driving range and lowering the charging times of lithium-ion batteries. However, improvements in lithium-ion technology appear to be proving incremental rather than exponential. “ (From LWP’s announcement on June 16th)

    Despite the exciting developments in the field of Li-Ion battery technology in the past decade, resulting in the application of lithium ion batteries in areas ranging from small portable electric devices to large power systems such as hybrid electric vehicles, the maximum energy density of current Li-Ion battery chemistry is not sufficient to meet the demands of new markets in such areas as electric vehicles. This is a fact.
    That is the reason new electrochemical systems with higher energy densities are being sought, and METAL-AIR BATTERIES with conversion chemistry are considered a promising candidate. More recently, promising electrochemical performance has driven much research interest in Li-Air Al-Air and Zn-Air batteries.

    PLW/GrapenEra is now offering one these Metal-Air battery technologies; Aluminium-Graphene-Oxygen battery technology; a Metal-Air battery with addition of GRAPHENE.
 
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