User:UlrichErnstCH/sandbox
Introduction
[edit]The Blackstone Battery Code system was created internally by Blackstone Resources AG as a consequence of the company's research into battery technology. In 2018, the coding system was made open-source under the creative commons licencing system. It is hoped that this could help enhance the depose process for batteries and support new recycling technologies.
The coding system identifies the battery metal mix of the battery, along with its chemistry and the technology it uses. It could one be used to help commoditise a single form-factor format that is currently use domestically for over-the-counter batteries used in retail appliances i.e. AA and AAA batteries that are defined by the American standard specification for dry cells with was created by the American National Standards Institute.
How it works
[edit]The coding system identifies the technology used and the elements used within. Each code is broken down into four section. Section one identifies the coding system i.e. BBC. Second two defines the technology type and elements used, such as lithium and cobalt. Section three explain the proportion of each element used, rounded to the nearest decile percentage. Finally, section four explains whether any additional elements have been used.
BBC designation codes for rechargeable batteries
[edit]BBC Code | Name | Chemical composition | Application | Comments |
---|---|---|---|---|
BBC LC 19 O | Lithium Cobalt Oxide (LCO) | LiCoO2 | Mobile phones, tablets, laptops, cameras | Very high specific energy limited specific power. Cobalt is expensive. Serves as Energy Cell. Market share has stabilised. |
BBC LNCA 1711 O | Lithium Nickel Cobalt Aluminium Oxide (NCA) | LiNiCoAlO2 | Medical devices, industrial, electric powertrain (Tesla) | Shares similarities with Li-cobalt. Serves as Energy Cell. |
BBC LM 19 O | Lithium Manganese Oxide (LMO) | LiMn2O4 | Power tools, medical devices, electric powertrains | High power but less capacity; safer than Li-cobalt; commonly mixed with NMC to improve performance. |
BBC LFP 163 O | Lithium Iron Phosphate (LFP) | LiFePO4 | Portable and stationary needing high load currents and endurance | Very flat voltage discharge curve but low capacity. One of safest Li-ions. Used for special markets. Elevated self-discharge. |
BBC LNMC 1333 O | Lithium Nickel Manganese Cobalt Oxide (NMC) | LiNiMnCoO2 | E-bikes, medical devices, EVs, industrial | Provides high capacity and high power. Serves as Hybrid Cell. Favourite chemistry for many uses; market share is increasing. |
BBC LNMC 1432 O | ||||
BBC LNMC 1522 O | ||||
BBC LNMC 1621 O | ||||
BBC LNMC 1711 O | ||||
BBC AC 28 | Aluminium-ion[1] | AlCl4 | Still in experimental stages. Yet to be deployed fully. | Aluminium-ion batteries are conceptually similar to lithium-ion batteries, but possess an aluminium anode instead of a lithium anode. |
BBC AC 37 | Aluminium-ion | Al2Cl7 | ||
BBC NZ 55 | Nickel-zinc | NiZn | A rechargeable battery used in household appliances. | Designed by Thomas Edison: the inventor of the light bulb. It’s been around for more than 100 years. |
BBC NF 55 | Nickel-iron | NiFe | Used in Europe’s mining operations because of their ability to withstand vibrations, high temperatures and other physical stress | A very robust battery that is tolerant to overcharging and short circuiting. |
BBC NC 55 | Nickel-cadmium | NiCd | Once widely used in power tools, flashlights and remote-control cars | NiCd rapidly lost market share in the early 1990s TO NiMH and Li-ion batteries. |
BBC NH 37 | Nickel-hydrogen | NiH2 | Used for energy storage in space probes | While the energy density is only one-third of a lithium battery, it has a very long life. |
BBC NM 55 | Nickel-metal hydride | NiMH | Used in digital cameras and other high-drain devices, where over the duration of single-charge use they outperform primary (such as alkaline) batteries. They are also used extensively in electric vehicles. | A NiMH battery can have two to three times the capacity of an equivalent size NiCd, and its energy density can approach that of a lithium-ion battery. |
BBC LNMC 1333 OG | Lithium Graphite/NMC | LiNiMnCoO2 | The battery of choice for power tools, e-bikes and other electric powertrains. | This is a standard NMC-type lithium battery, where graphite is used to speed up charge times. |
BBC LT 46 O | Lithium Titanate Oxide | Li2TiO3 | Used in some electric vehicles, such at the Mitsubishi i-MiEV. Honda also uses them in it Fit EV electric bike. | The lithium-titanate battery is a type of rechargeable battery which has the advantage of being faster to charge than other lithium-ion batteries. |
Battery characteristics
[edit]BBC Code | Name | Voltage | Capacity | Lifecycle |
---|---|---|---|---|
BBC LCO 19 | Lithium Cobalt Oxide (LCO) | 3.0-4.2V | 150-200Wh/kg | 500-1000 |
BBC LNCA 1711 | Lithium Nickel Cobalt Aluminium Oxide (NCA) | 3.0-4.2V | 200-260Wh/kg | 500 |
BBC LMO 19 | Lithium Manganese Oxide (LMO) | 3.0-4.2V | 100-150Wh/kg | 300-700 |
BBC LFP 163 | Lithium Iron Phosphate (LFP) | 2.5-3.65V | 90-120Wh/kg | 1000-2000 |
BBC LNMC 1333 | Lithium Nickel Manganese Cobalt Oxide (NMC) | 3.0-4.2V | 150-220Wh/kg | 1000-2000 |
BBC LNMC 1432 | ||||
BBC LNMC 1522 | ||||
BBC LNMC 1621 | ||||
BBC LNMC 1711 | ||||
BBC AC 28 | Aluminium-ion[2] | 2.65V | 800-1,060Wh/kg | 10000 |
BBC AC 37 | Aluminium-ion | 2.65V | 800-1,060Wh/kg | 10000 |
BBC NZ 55 | Nickel-zinc | 1.2V | 19-25Wh/kg | 30-50 years |
BBC NF 55 | Nickel-iron | 1.6V | 100Wh/kg | 800 |
BBC NC 55 | Nickel-cadmium | 1.2V | 40-60Wh/kg | 2000 |
BBC NH 37 | Nickel-hydrogen | 1.25V | 55-75Wh/kg | 20000 |
BBC NM 55 | Nickel-metal hydride | 1.2V | 250-1,000Wh/kg | 180-2,000 |
BBC LNMC 1333 OG | Lithium Graphite/NMC8 | 3.6V | 120-200Wh/kg | 500-3,000 |
BBC LT 46 O | Lithium Titanate Oxide | 2.3V | 70-80Wh/kg | 15,000-20,000 |
- ^ Zafar, Z.A. (2017). "Cathode materials for rechargeable aluminum batteries". Retrieved 6 December 2018.
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(help) - ^ Zafar, Z.A. (2017). "Cathode materials for rechargeable aluminum batteries". Retrieved 6 December 2018.
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