Smart Heat Storage for solar heating systems Simon Furbo Department of Civil Engineering Technical University of Denmark Brovej – bygning 118 DK-2800 Kgs. Lyngby Denmark Email: [email protected]
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Smart Heat Storage for solar heating systems
Simon Furbo Department of Civil Engineering Technical University of Denmark
Brovej – bygning 118 DK-2800 Kgs. Lyngby
Denmark Email: [email protected]
2 Source: Common Vision for the Renewable Heating & Cooling sector in Europe European Technology Platform on Renewable Heating and Cooling
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Renewables Potentials
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Denmark 2050: All fossil fuels phased out - 2035: All heat and electricity from renewables
Wind energy: 2014, first 6 months: 41% of electricity consumption 2020: 50 % of increased electricity consumption (incl. transport, heat pumps, …) Solar heating: 2030: 15% of decreased heating demand 2050: 40% of decreased heating demand - 80% of this by solar heating plants & 20% individual systems
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0
10
20
30
40
50
60
70
0 20 40 60
Eur/
MW
h Week No
Nord Pool Weekly 2012
EUR/MWh(DK)
EUR/MWh(NO)
Poly.(EUR/MWh(DK))
Poly.(EUR/MWh(NO))
Problem: As renewable electricity production increases: • mismatch of production and load will increase • dynamics of the elctricity price will increase
Solar heating systems must have a good interplay with liberal electricity market
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Interplay with liberal electricity market
Solution: Combined technologies and smart heat storage interacting with the electricity grid …
Heat Pum
p CHP
gasmotor
Backup boiler on biomass
Load/usage
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Solar: Produce free heat
Heat pump: Produce cheap heat Fast capacity regulation
(load) earn money Reduce storage volume
CHP: Produce valuable
electricity earn money Fast capacity regulation
(prod.) earn money Smart heat storage: Gives the flexibility Makes the combinations
of technologies possible
Benefits from combining technologies and using heat storage
HP CH
P
Boiler
Load/usage
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Danmark west, 2007 - from Nordpool
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Solar heating plant - principle
Forbrugere Solfangerfelt Consumers
District heating boiler plant
Solar collector field
Heat exchanger
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Jægerspris 13405 m²
Ulsted 5012 m²
Dronninglund 37573 m²
Marstal 33365 m²
Solar heating plants
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Total solar collector area of Danish solar heating plants
0
100000
200000
300000
400000
500000
600000
2005 2006 2007 2008 2009 2010 2011 2012 2013 2014
Col
lect
or a
rea,
m²
Year
12
Interaction with dynamic electricity production Simple solar heating plants with solar fractions of 5-25% are most common so far, collector areas about 10000 m² But it seems also to be cost effictive to go for higher solar fractions/long term heat storage due to: • Simple heat storage technologies • Large heat storages with small heat losses and low costs per volume
• Interplay with liberal electricity market • Advantages by combining technologies
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Cheap storage technology, water pond and borehole storage
No insulation to earth !
Heat capacity per volume: • Water: 4.1 MJ/Km3 • Soil: About 2.7 MJ/Km3
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Marstal - seasonal heat storage - 75000 m3 water pond
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Dronninglund - seasonal heat storage - 60000 m3 water pond
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-
0,20
0,40
0,60
0,80
1,00
1,20
100
1.0
00
10.
000
100
.000
Are
a /
vol
um
e [m
²/m
3]
Volume [m3]
Surface area per volume (Cylinder, Radius = Height)
LARGE SYSTEMS small storage losses & lower specific costs
1.2 0.1 Factor 12 on surface area/volume (heat loss/storage capacity(
0
50
100
150
200
250
300
350
400
450
500
100 1,000 10,000 100,000
Inve
stm
ent c
ost p
er m
³ wat
er e
quiv
alen
t [€/
m³]
Storage volume in water equivalent [m³]
realisedstudyTanksPitsBTESATES
Neckarsulm(1. phase)
Rottweil
Stuttgart
Hamburg
Friedrichshafen (HW)
Berlin-Biesdorf
Potsdam
Chemnitz
Rostock
Steinfurt (K/W)
Bielefeld
Hanover
Ilmenau
Kettmann-hausen
Crailsheimf
Munich
CrailsheimA if
Eggenstein
500 20 Factor 25 on costs/volume (cost/storage capacity)
Source: SOLITES
Cost per equivalent m3
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•Water ponds under construction:
• Vojens: 200000 m3
• Gram: 110000 m3
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19000 m3 borehole storage in Brædstrup
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Design and implementation, Brædstrup
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Design and implementation, Brædstrup
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Measurements Borehole storage, Brædstrup Water pond storage,
Marstal Size 19000 m3 soil, corresponding
to about 12000 m3 water 75000 m3 water
Prize 240000 euro, coprresponding to about 20 euro/m3 water
2400000 euro, corresponding to 32 euro/m3 water
Maximum storage temperature
50°C 90°C
Heat recovered from heat storage during first year, 2012-2013
44% 18%
Heat recovered from heat storage during second year, 2013-2014
38% 65%
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Individual solar/electric heating systems with smart heat storages, which can be heated by solar collectors and by electricity in periods with low electricity prices
Individual solar/electric heating system for the future smart energy system
• Heat is produced by solar collectors and by electric heating elements or a heat pump • Electric heating elements/heat pump if possible only in operation in periods where solar heat can
not fully cover heat demand and where the electricity price is low • System equipped with a smart heat storage (variable auxiliary volume) and a smart control
system based on prognoses for: – heat demand – solar heat production – electricity price
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Electricity price, DKK/MWh Denmark west, November 3.-9., 2008
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Smart solar tanks for solar heating systems Marketed Solar tank Smart solar tank
TANK HEATED FROM THE TOP INDIVIDUAL FLEXIBLE TIMER/ENERGY CONTROL SYSTEM
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Solar heating systems with smart solar tanks
Increased thermal performance by up to 35% due to: Decreased tank heat loss
Increased solar heat production
Further, also additional improved cost efficiency due to: Use of low electricity price
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Systems tested side by side
• 9 m² solar collector • 735 l smart solar tank. Auxiliary: One electric heating element, three electric heating elements, heat pump • Smart control system - heat content in tank, weather forecast, coming heat demand, coming solar heat production, coming
electricity prices from NORDPOOLSPOT
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Inlet stratifier Inlet
stratifier
3 kW
3 kW
3 kW
Inlet stratifier
HP 9 kW
PEX pipe
Auxiliary heating principles
Solar collector loop & discharge loops
Cold and hot water
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Measured results for spring 2013 • Electricity consumption of system with electric heating element(s) = 2.2 x electricity consumption
of system with heat pump
• Heat price for systems with electric heating element(s) = 2 x Heat price for system with heat pump
Theoretical calculations - results Home owner • Heat price for house: 100% • Heat price for house with 10 m² solar combi system: 70-80% Strongly influenced on policy on tax on electricity: • Heat price for house with 10 m² smart solar heating system with electric heating elements
and variable electricity price: 65-75% • Heat price for house with 10 m² smart solar heating system with heat pump and variable
electricity price: 35-40%
Society • Socio-economic benefit of smart solar heating systems compared with a reference
scenario with oil and gas boilers: The total benefit: 2200 - 6100 DKK per system per year
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Conclusions Centralised solar heating systems with smart long term heat stores • Water pond and borehole storages promising technologies for solar heating plants Individual solar heating systems with smart solar heat stores • Individual smart solar heating systems with electric heating elements/heat pump and
variable electricity price are more cost-effective than traditional solar heating systems
• Individual smart solar heating systems with electric heating elements/heat pump can help integrating wind power in the energy system and contribute to an increased share of renewable energy
Recommendations Increase research, development and demonstration efforts on: • Water ponds • Borehole storages • Individual smart solar/electric heating systems for low energy buildings • Individual smart solar/heat pump systems for normal houses
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Thank you for your attention
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