energy storage, thermal energy storage (tes) - Åbo …web.abo.fi/~rzevenho/pet15-4-tes.pdf ·...
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Energy storage, Thermal energy storage (TES)
Ron ZevenhovenÅbo Akademi University
Thermal and Flow Engineering Laboratory / Värme- och strömningstekniktel. 3223 ; [email protected]
Process EngineeringThermodynamicscourse # 424304.0 v. 2015
ÅA 424304
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4.1 Energy storage
Energy storage - motivationsSeveral reasons motivate the storage of energy, either as heat, cold, or electricity:
– Supplies of energy are in many cases intermittent: supply / demand mismatch
– Increased efficiency of energy use must be part of the future’s energy distribution and use methods
– Improved materials based on nanotechnology (for example) allow for more advanced energy-relatedapplications
– Linked to renewable energy phase-in / fossil energyphase-out
• less emissions to the atmosphere and other environmental impactbut (!) not necessarily water-use-efficient.
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Energy storage – options 1/2 To be distinguished: storage of energy as physical
exergy, and storage as chemical exergy (fuels, batteries)
This gives the following main options:1. Storing energy as chemicalexergy electricity in batteries (chemical potential) or using heat or power to produce fuel (e.g. H2, ethanol) or reduced oxides (Si, Zn), including ”solar fuels”
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Picture: http://www.intechopen.com/books/application-of-solar-energy/fuel-production-using-concentrated-solar-energy
Energy storage – options 2/2 This gives the following main options:
2. Storing energy as physical exergy:• Potential energy storage (e.g. pumped hydropower)• Compression/expansion of gas (e.g. compressed air storage)• Thermal storage as sensible heat: specific heat × Δ temperature• Thermal storage as latent heat: heat of vaporisation, condensation
Important are, besides (of course) energy storage density(ESD), (J/kg or J/m3):– Reversibility (i.e. repeatability) and stability (e.g. battery life,
melt/solidify/melt/solidify ....... stability)– Size and weight– Complexity and of course costs (capex, opex)
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Mechanical energy storage: hydro
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Pictures: DR02
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Mechanical energy storage: air
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Pictures: DR02
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Chemical energy: batteries
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USABC US Advanced Battery Consortium targets
Pictures: DR02
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Chemicalenergy: chemicalheat pump
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Picture: DR02
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ES technology comparison 1/2
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Abbrevations & legend: next slide Source: DR02
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ES technology comparison 2/2
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Source: DR02
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ES equipment costs and efficiencies
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Source: DR02
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Thermal energy storage: water
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Picture: DR02
~ 2200 kJ/kg
~ 4,2×ΔT kJ/kg
~ 330 kJ/kg
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Nanomaterials for TES
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TES applications:- Building heating / cooling
e.g. PCM materials- Electronics- Automotive, IC engine- Solar collectors
Source: DR02
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4.2 Thermal energy storage: heat
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General TES stages & types
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Diurnal: hours – a daySeasonal: weeks - months
Source: DR02
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Solar energy driven TES
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Rock-bed/ solar TES
Solar storage tanks: (a) Direct link to collector;
(b) Sensible TES with heat exchanger; (c) Thomason’s technique with both
water and stone as storage media
Source: DR02
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Thermal stratification TES
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Types and configurations ofstorage tanksHX = heat exchangerHTF = heat transfer fluid
Source: DR02
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Aquifer TES (ATES)
Heat pump + ATES
Source: DR02
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Solar ponds
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(see also course part 2b, and ÅA course New Energy Technologies)Source: DR02
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Evacuated solar collector TES
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(see also course part 2b, and ÅA course New Energy Technologies)Source: DR02
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Phase change materials (PCMs)
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Source: http://www.climatetechwiki.org/technology/jiqweb-pcm-0
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Phase change materials (PCMs)
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Source: DR02
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PCMs physical properties 1/2
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......continues on next pageSource: DR02
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PCMs physical properties 2/2
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Source: DR02
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MgCO3 (from large-scale CO2
mineralisation) and TES
See also PCT/US97/15577:
2
MgCO3 + xH2O MgCO3.xH2O + heat
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4.3 Thermal energy storage: cold
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Cold thermal energy storage (CTES)
Night-time off-peak (cheaper) energycan be stored (batteries) for day-timepeak use for air conditioning
Cooling capacity can be stored as coldor frozen water, or other materials such as glycol and eutectic salt + water systems
Also special phase transitionmaterials (PCMs) were developed
Note also that with loweroutside (night-time) temperatures, cooling and freezing processes are more efficient!
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PCMs: see http://www.teappcm.com/ (Accessed Nov. 2014)
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Chilled water cold TES
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Source: DR02
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Cold thermal energy storage
Pictures: DR02
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Cold thermal energy storage
Pictures: DR02
Atmospheric and pressurised ice ball tanks (CRYOGEL)
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Sources
DR02: Dinçer, I, Rosen, M A, Thermal energy storage, Wiley & Sons (2002) DR10: ……. 2nd edition (2010), available (for ÅA students) at:http://ezproxy.abo.fi/login?url=http://site.ebrary.com/lib/abo/Doc?id=10419102
A-K13: H H Al-Kayiem, S C Lin and A Lukmon. Review on Nanomaterials for Thermal Energy Storage Technologies. Nanoscience & Nanotechnology - Asia, 2013, 3, 60-71
ESA: Energy storage association http://energystorage.org/