Large-Scale Pumped Thermal Electricity Storages—Converting Energy Using Shallow Lined Rock Caverns, Carbon Dioxide and Underground Pumped-Hydro

Lalanne, Pascal; Byrne, Paul

doi:10.3390/app9194150

Cited by 7 publications

(5 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…An example of hard rock caverns is that in Sweden (Skallen project) (Fig. 22) which was used for natural gas storage [418,480,481]. It has also received storage applications for waste management purposes [418].…”

Section: Hard Rock Caverns and Abandoned Minesmentioning

confidence: 99%

Hydrogen production, transportation, utilization, and storage: Recent advances towards sustainable energy

Muhammed,

Gbadamosi,

Epelle

et al. 2023

Journal of Energy Storage

View full text Add to dashboard Cite

Section: Hard Rock Caverns and Abandoned Minesmentioning

confidence: 99%

Hydrogen production, transportation, utilization, and storage: Recent advances towards sustainable energy

Muhammed,

Gbadamosi,

Epelle

et al. 2023

Journal of Energy Storage

View full text Add to dashboard Cite

“…Aware of the urgency of addressing climate change by increasing the share of solar and wind energy in the global energy mix, Lalanne et al described in a previous article the concept of an Underground Pumped Hydro Energy Storage (UPHES) for large-scale storage of solar and wind energy [22]. The three proposed directions were: 1-using shallow high-pressure LRC (Lined Rock Cavern); 2-using a slow-moving CO 2 piston at the same pressure as the hydro part of the UPHES (pressure transmission is carried out through a membrane); 3-relying on inexpensive atmospheric thermal pits for longduration storage.…”

Section: Introductionmentioning

confidence: 99%

“…The cold pit could contain salt hydrates at a temperature between −10 and −45 • C. In the light of this literature review, a development of the concept previously published in ref. [22], but for an aerial installation, is proposed in this article. It presents an energy storage system using transcritical CO 2 cycles and pumped-hydro technology to produce and store thermal energy in reservoirs for a long-term duration (5 to 500 h).…”

Section: Introductionmentioning

confidence: 99%

Parametric Study of a Long-Duration Energy Storage Using Pumped-Hydro and Carbon Dioxide Transcritical Cycles

Byrne

Lalanne

2021

Energies

Self Cite

View full text Add to dashboard Cite

The urgent energy transition needs a better penetration of renewable energy in the world’s energy mix. The intermittency of renewables requires the use of longer-term storage. The present system uses water displacement, in a lined rock cavern or in an aerial pressurised vessel, as the virtual piston of compressor and expander functions in a carbon dioxide heat pump cycle (HPC) and in an organic transcritical cycle (OTC). Within an impermeable membrane, carbon dioxide is compressed and expanded by filling and emptying pumped-hydro water. Carbon dioxide exchanges heat with two atmospheric thermal storage pits. The hot fluid and ice pits are charged by the HPC when renewable energy becomes available and discharged by the OTC when electricity is needed. A numerical model was built to replicate the system’s losses and to calculate its round-trip efficiency (RTE). A subsequent parametric study highlights key parameters for sizing and optimisation. With an expected RTE of around 70%, this CO2 PHES (pumped-hydro electricity storage) coupled with PTES (pumped thermal energy storage) could become a game-changer by allowing the efficient storage of intermittent renewable energy and by integrating with district heating and cooling networks, as required by cities and industry in the future.

show abstract

“…Including all loss coefficients, it is stated that turnround efficiency for PTES between 40 and 70% is feasible (McTigue et al, 2019). Lalanne and Byrne (2019), also in 2019, presented a Large-Scale Pumped Thermal Electricity Storage system using CO 2 as the working fluid combined with an underground pumped hydro system that used lined rock caverns to house the storage media. A steel lining is used for sealing and then a concrete backfill structure is used to transfer the pressure forces from pressurized gas in the container to the bedrock.…”

Section: Introductionmentioning

confidence: 99%

An Analysis of Pumped Thermal Energy Storage With De-coupled Thermal Stores

Davenne

Peters

2020

Front. Energy Res.

View full text Add to dashboard Cite

Results from the first demonstration of Pumped Thermal Energy Storage (PTES) were published in 2019, indicating an achieved turn-round efficiency of 60-65% for a system capable of storing 600 kWh of electricity. PTES uses a theoretically reversible thermodynamic cycle involving compression and expansion stages with constant pressure heat addition and rejection to hot and cold thermal stores. Energy storage turn-round efficiency largely depends on the isentropic efficiencies of the compression and expansion equipment, the thermal effectiveness of the thermal stores, the presence of circuit pressure drops, heat leaks to and from the system and electrical machine efficiencies. We present a simulation model of a PTES system which is used to produce an inventory of the relative magnitudes of the various system losses. We consider the feasibility of a large-scale, 1 GWh nominal storage capacity, PTES system with de-coupled thermal stores; and provide comparison with the so far more investigated, coupled system. Based on ambitious yet realistic component performances, we calculate an energy storage turn around efficiency of 65.3 and 59.5% for the coupled and de-coupled systems, respectively. Even with dwell times in the charged state as long as 5 days, a turn-round efficiency of over 50% is still predicted in both systems; suggesting that PTES could offer a viable large-scale, long duration energy store.

show abstract

Large-Scale Pumped Thermal Electricity Storages—Converting Energy Using Shallow Lined Rock Caverns, Carbon Dioxide and Underground Pumped-Hydro

Cited by 7 publications

References 18 publications

Hydrogen production, transportation, utilization, and storage: Recent advances towards sustainable energy

Hydrogen production, transportation, utilization, and storage: Recent advances towards sustainable energy

Parametric Study of a Long-Duration Energy Storage Using Pumped-Hydro and Carbon Dioxide Transcritical Cycles

An Analysis of Pumped Thermal Energy Storage With De-coupled Thermal Stores

Contact Info

Product

Resources

About