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#1
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CO2 batteries -long duration
The basic principle involves a closed-loop CO2 system with these main steps:
Charging Phase: CO2 is compressed and heated, turning it into a supercritical fluid This hot, pressurized CO2 is stored in high-pressure vessels The thermal and pressure energy is effectively "stored" Discharging Phase: The pressurized CO2 is released through turbines As it expands, it drives the turbines to generate electricity The CO2 cools and returns to its gaseous state It's then recaptured to restart the cycle Key companies/technologies to research: Energy Dome (Italian company) - has built commercial demonstration plants Highview Power - while they use liquid air, their technology principles are similar Malta Inc - works on related thermal energy storage systems Benefits: Round-trip efficiency can reach 75-80% Storage duration from hours to days Uses abundant, non-toxic materials Lower geographical constraints compared to pumped hydro Lower cost potential compared to lithium-ion for long duration Challenges: Infrastructure costs for pressure vessels Need for efficient heat management Scaling up the technology Optimizing compression/expansion cycles For authoritative information, I'd recommend checking: Energy Dome's technical documentation (energydome.com) Department of Energy's energy storage database Academic papers from organizations like NREL or MIT on CO2-based energy storage
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
#2
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Co2 long duration battery Cost advantages?
Estimated Levelized Cost of Storage (LCOS) in USD/kWh:
CO2 Batteries: $50-100/kWh (projected at scale) Lithium-ion: $150-400/kWh Vanadium Redox Flow (VRB): $150-300/kWh Pumped Hydro: $150-200/kWh Key cost advantages of CO2 batteries: Materials Uses abundant CO2 vs rare/expensive materials No lithium, cobalt, or vanadium required Less supply chain risk No material degradation over time Lifecycle Costs 20-30 year lifespan with minimal degradation Lower maintenance requirements No electrolyte replacement (unlike VRB) No battery cell replacement (unlike Li-ion) Scaling Advantages Cost decreases significantly with scale Simpler construction than VRB No membrane costs Standard industrial components (turbines, heat exchangers) Limitations to consider: Higher upfront capital costs Less proven technology Infrastructure requirements Current lack of manufacturing scale Worth noting that these costs are based on projections and early deployments - the technology is still maturing. ore: https://claude.site/artifacts/835e0e...e-7a50127faccf
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
#3
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Co2 compression resources and powered by green energy?
CO2 compression in the context of renewable energy integration:
Compression Requirements: Compression Power Needs Typically requires 2-3 MW per 10 MWh storage capacity Multi-stage compression for efficiency Operating pressures: 70-150 bar Temperature management crucial Renewable Integration Options: Solar PV + CO2 Battery Use excess solar during peak hours Buffer for night/cloudy periods Good match with daily cycles Thermal energy from solar can assist compression Wind + CO2 Battery Store excess wind energy during high generation Cover wind lulls Match variable wind patterns Cold exhaust air can help cooling Geothermal + CO2 Battery Constant baseload for compression Use geothermal heat to enhance efficiency Combined heat-power systems possible Year-round availability Key Equipment/Technologies: Industrial CO2 compressors (reciprocating/centrifugal) Heat exchangers for thermal management Pressure vessels (storage) Smart control systems for renewable integration Companies/Resources to research: MAN Energy Solutions (CO2 compressors) Atlas Copco Australia Siemens Energy -Australia Energy Dome's technical https://www.popularmechanics.com/sci...gy-dome-plant/ https://netl.doe.gov/sites/default/f...ES_Ferrari.pdf
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
#4
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Solar Charged CO2 battery Vs SMR costs
SMR (100 MWe):
Capital cost: ~$600-900 million Land: 10-15 acres ($50,000-150,000) Transmission: Relatively simple due to compact footprint (~$2-5 million) Operating costs: ~$25-30/MWh Decommissioning: ~$100-200 million Lifetime: 40-60 years Solar + CO2 Battery (to match 100 MWe firm): Solar panels (~750,000): ~$150-200 million Land (1.5-2 kmē): ~$3-7 million CO2 Battery (Malta or similar system for 12-16 hour storage): ~$200-300 million Transmission (more complex due to distributed nature): ~$10-20 million Operating costs: ~$10-15/MWh Decommissioning: ~$20-30 million Lifetime: 25-30 years (panels), 30+ years (storage) Total Levelized Cost (LCOE): SMR: ~$60-100/MWh Solar+Storage: ~$70-110/MWh Key considerations: Solar costs continue declining while SMR costs have been relatively stable CO2 battery technology is new and costs may decrease significantly SMRs have longer lifetime but higher decommissioning costs Regulatory costs for nuclear typically higher Insurance costs higher for SMR
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
#5
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Wind Charged CO2 battery Vs SMR costs
Wind + CO2 Battery (to match 100 MWe firm):
Wind turbines (25-30 x 4MW turbines): ~$150-180 million Land (spacing needed ~25-30 kmē, but most can be dual-use farmland): ~$1-2 million lease costs annually CO2 Battery (for 8-12 hour storage, less than solar needs): ~$150-250 million Transmission (more complex, longer distances): ~$20-40 million Operating costs: ~$15-20/MWh Decommissioning: ~$25-35 million Lifetime: 20-25 years (turbines), 30+ years (storage) SMR (100 MWe) - for comparison: Capital cost: ~$600-900 million Land: 10-15 acres ($50,000-150,000) Transmission: ~$2-5 million Operating costs: ~$25-30/MWh Decommissioning: ~$100-200 million Lifetime: 40-60 years Total Levelized Cost (LCOE): SMR: ~$60-100/MWh Wind+Storage: ~$65-95/MWh Key differences from solar: Wind has higher capacity factor (~35-45% vs ~20-25% for solar) Needs less storage capacity than solar Requires more land but allows dual-use More consistent day/night output Transmission costs typically higher due to remote locations Lower visual density (more spread out)
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
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