Statements (48)
| Predicate | Object |
|---|---|
| gptkbp:instanceOf |
redox flow batteries
|
| gptkbp:acidity |
vanadium sulfate
|
| gptkbp:application |
renewable energy integration
backup power systems grid energy storage load leveling |
| gptkbp:benefits |
long cycle life
safety scalability high cost complexity of system |
| gptkbp:businessModel |
increasing demand
growing interest in renewable energy investment in energy storage technology |
| gptkbp:climate |
-20 to 50 °C
|
| gptkbp:component |
gptkb:vanadium
pumps tanks membrane negative electrode positive electrode |
| gptkbp:developedBy |
NASA
|
| gptkbp:energyEfficiency |
70-80%
20-30 Wh/kg |
| gptkbp:environmentalImpact |
recyclable materials
low toxicity |
| gptkbp:futurePlans |
increased efficiency
advancements in materials science lower costs integration with smart grids wider adoption in commercial applications |
| gptkbp:hasPartnershipsWith |
1980s
|
| https://www.w3.org/2000/01/rdf-schema#label |
Vanadium redox batteries
|
| gptkbp:is_a_key_player_in |
gptkb:Sumitomo_Electric
RedT Energy VRB Energy Invinity_Energy_Systems UniEnergy_Technologies |
| gptkbp:lifespan |
up to 25 years
|
| gptkbp:maintenance |
low maintenance requirements
|
| gptkbp:operationalStatus |
redox reactions
|
| gptkbp:powers |
5-10 kW/m³
|
| gptkbp:relatedTo |
lithium-ion batteries
lead-acid batteries |
| gptkbp:researchFocus |
improving efficiency
reducing costs increasing energy density |
| gptkbp:usedIn |
energy storage systems
|