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Energy Economics
• Presentations
• Literature
– Taylor, G., Tanton, T. 2012. The hidden cost of wind electricity. American tradition institute. http://www.atinstitute.org/wp-content/uploads/2012/12/Hidden-Cost.pdf
– Hirth, L. 2013. The optimal share of variable renewables. How the variabiity of wind and solar power affects their welfare-optimizing deployment. FEEM Working Paper 90.2013. http://papers.ssrn.com/sol3/papers.cfm?abstract_id=2351754
– Kirchen. Chapter 1
• How expensive are renewables after all?
The technology behind crystalline silicon solar cells has profited from extensive developments in the multi-billion-dollar microelectronics industry.
About 20 years ago, a kilowatt of solar energy cost about 50 euro cents ($0.69) to produce, today in Germany it's about 10 euro cents - while in sunny regions it's between 5 and 8 euro cents.
So worldwide, we're totally competitive with, and often even cheaper than, fossil fuels.
http://www.dw.de/at-the-floodgates-of-a-solar-energy-boom/a-17259267
Professor Eicke R. Weber is the Director of the Fraunhofer Institute for Solar Energy Systems ISE and professor of physics/solar energy at the Department of Mathematics and Physics and the Department of Engineering respectively at the University of Freiburg, Germany.
http://www.ise.fraunhofer.de/en/about-us/director-and-division-directors/prof.-eicke-weber
Can this be true?
Why give subsidies still?
• http://www.cityam.com/article/1392944530/how-free-markets-are-making-solar-energy-feasible-without-subsidies
http://cleantechnica.com/2013/12/16/solar-gird-parity-infographic-important-addendum/
http://solarcellcentral.com/cost_page.html
2013
€1-2/W
Capital costs of PV have fallen with 85%-90% since 1998
(from $12 -> $1-2 per Wpc)
http://www.ise.fraunhofer.de/en/publications/veroeffentlichungen-pdf-dateien-en/studien-und-konzeptpapiere/study-levelized-cost-of-electricity-renewable-energies.pdf/view
• Refinements:1. Explicitly model intermittent (solar+wind) +
backup2. Model the value of electricity produced by
intermittent generation
1. Explicitly model intermittent (solar+wind) + backup
• Wind and solar should better be seen as:– Wind and solar + gas backup (round 90%)– Wind and solar + coal backup (round 90%)
• Taylor, G., Tanton, T. 2012. The hidden cost of wind electricity. American tradition institute. http://www.atinstitute.org/wp-content/uploads/2012/12/Hidden-Cost.pdf
Source: Energy Information Administration 2012 Annual Energy Outlook
Source: Energy Information Administration 2012 Annual Energy Outlook
• This report has shown that the cost wind electricity is not approaching parity with conventional sources, and is unlikely to reach parity – unless the price of natural gas, the price of
coal and the capital cost of nuclear facilities were all to increase dramatically.
• Study applies to US– 3% of energy generated by wind
• Germany– Has higher wind penetration– 7~8% of energy generated by wind
• What is the effect of an increase in wind penetration on costs?
2. Model the value of electricity produced by intermittent generation
• Hirth, L. 2013. The optimal share of variable renewables. How the variabiity of wind and solar power affects their welfare-optimizing deployment. FEEM Working Paper 90.2013.
http://papers.ssrn.com/sol3/papers.cfm?abstract_id=2351754
Levelized costs:
Levelized value:
Where (exact):
Over lead times Over timesOver places
Approximation
• We define profile costs as the price spread between the load-weighted and wind-weighted day-ahead electricity price for all hours during one year. Profile costs arise because of two reasons. On the one hand, demand and VRE generation are often (positively or negatively) correlated. A positive correlation, for example the seasonal correlation of winds with demand in Western Europe, increases the value of wind power, leading to negative profile costs.
• On the other hand, at significant installed capacity, wind “cannibalizes” itself because the extra electricity supply depresses the market price whenever wind is blowing. In other words, the price for electricity is low during windy hours when most wind power is generated. Fundamentally, profile costs exist because electricity storage is costly, recall physical constraint i). A discussion of profile costs and quantitative estimates are provided by Lamont (2008), Borenstein (2008), Joskow (2011), Mills & Wiser (2012), Nicolosi (2012), Hirth (2013), and Schmalensee (2013).
• wind “cannibalizes” itself because the extra electricity supply depresses the market price whenever wind is blowing
Remember how wind was cannabalized in the model of lecture W07.2F
• Profile cost: wind produces most when the price is low
• Profile cost: wind produces most when the price is low• Balancing cost: forecasting errors
– wind produces is “out-of-balance”, produces more or less than promised
– Cycling costs of plants
• Profile cost: wind produces most when the price is low• Balancing cost: forecasting errors
– wind produces is “out-of-balance”, produces more or less than promised– Cycling costs of plants
European ClimateFoundation 2050:
• Increase from 34 GW to 127 GW
• 400% increase
The future of the EU transmission network
Authors wont model the losses due to location (grid costs) were not modeled
• Profile cost: wind produces most when the price is low• Balancing cost: forecasting errors
– wind produces is “out-of-balance”, produces more or less than promised– Cycling costs of plants
• Grid costs: wind produces far away from demand– Cost of additional transmission
• Cost change with penetration (cannabilization effect)
• So far are theoretical models, what do the numbers tell us?– Use of a dispatch model, feeding realistic data– Northwestern Europe: Germany, Belgium,
Poland, The Netherlands, and France
3% 20%
Wind
Wind
If wind blew constantly
If wind was variable but perfectly predictable
True situation
Note that losses due to location (grid costs) were not modeled
LCoE use the simplification that wind blows constantly.
This simplification seems to explains the wide gap in the debate on the usefulness of wind.
Assuming 30% fall in wind cost wrt today
• What is remarkable about this curve?• Optimal wind share with doubling of:
– Coal price -> increases– Gas price -> decreases
• Doubling coal prices -> optimal wind up by 5% points
• Halving gas prices (“shale gas”) -> optimal wind down
• Doubling gas prices -> optimal wind down.
• Doubling coal prices -> optimal wind up by 5% pointsfive percentage points (Figure 17).
• Lowering gas prices by half (“shale gas”) has a similarly expected effect,dramatically lowering optimal wind deployment.
• Surprisingly however, doubling gas prices reduces the optimal wind share.– As in the case of CO2 pricing, the reason for this
seemingly counterintuitive result can be found in the capital stock response to the price shock. Higher gas prices induce investments in hard coal, which has lower variable costs, reducing the value of wind power and its optimal deployment.
Solar
• Even at 60% cost reduction, the optimal solar share is below 4% in all but very few cases.
• Reason: the marginal value of solar power drops steeply with penetration,
– Even more so than wind. Why?
– Because solar radiation is concentrated in few hours
• In line with earlier studies (Nicolosi 2012, Mills & Wiser 2012, Hirth 2013).
Now: €1-2/W
Hirth + 60% cost reduction:€0.6/WHirth uses€1.6/W
2013
€1-2/W
http://www.bp.com/en/global/corporate/about-bp/energy-economics/statistical-review-of-world-energy-2013.html
• Energy revolutions
http://vaclavsmil.com/wp-content/uploads/scientificamerican0114-52.pdf
• Coal supplies more than 5 percent of energy– 1840
• fossil fuels (coal) surpasses use of biomass (wood and charcoal)– 1885 USA– 1875 France– 1901 Japan – 1930 U.S.S.R– 1965 China – 1970 India
• Oil supplies more than 5 percent of energy– 1915
• Oil surpasses use coal– 1964
Organization of electricity markets
• Organization of electricity markets1. Liberalization2. Transmission pricing (Nodal versus Zonal)
• Organization of electricity markets1. Liberalization
Kirchen. Chapter 1
Allow Independent Power Producers (IPP)(US: PURPA law 1978)
Add wholesale competition
Add retail competition
Close to the present model in EU
(but wholesale market and transmission system are separate)
Unbundling was a process over several years
S. van Koten, A. Ortmann / Energy Economics 30 (2008) 3128–3140
Unbundling was a process over several years
S. van Koten, A. Ortmann / Energy Economics 30 (2008) 3128–3140
Unbundling was a process over several years
S. van Koten, A. Ortmann / Energy Economics 30 (2008) 3128–3140http://www.cerge-ei.cz/pdf/pb/PB13.pdf
• Organization of electricity markets1. Liberalization2. Transmission pricing
• Nodal and zonal dispatch in meshed networks
• Peak-load pricing
900MW@20$/MWh
800MW@50$/MWh
900MW@20$/MWh
800MW@50$/MWh
Nodal pricing Zonal pricing
A B
400MW 300MW 400MW 300MW
A B
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
400MW 300MW@20$/MWh @20$/MWh
300MW400MW 300MW
@20$/MWh @20$/MWh
300MW
Nodal pricing Zonal pricing
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
A B
Bids for ancillary market (balancing market)
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
400MW 300MW@20$/MWh @50$/MWh
200MW400MW 300MW
@20$/MWh @20$/MWh
300MW
Nodal pricing Zonal pricing
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
Max: 200MWMax: 200MW
@30$/MWh
Price of transmission?
20
50
900 1700700
1st dispatch
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
400MW 300MW@20$/MWh @50$/MWh
200MW400MW 300MW
@20$/MWh @20$/MWh
200MW
Nodal pricing Zonal pricing
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
Max: 200MWMax: 200MW
@30$/MWh
Price of transmission?
20
50
900 1700700
-100MW @-10$= +10.000$
+100MW @70$= -80.000$
Cost of 70.000
1st dispatch
2nd dispatch
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
400MW 300MW@20$/MWh @50$/MWh
200MW400MW 300MW
@30$/MWh @30$/MWh
200MW
Nodal pricing Zonal pricing
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
A B
900MW@20$/MWh
+ @35$/MWh- (@-10$/MWh
800MW@50$/MWh
+ @70$/MWh- (@-20$/MWh
Max: 200MWMax: 200MW
@30$/MWh
Price of transmission?
20
50
900 1700700
2nd dispatch
-100MW @-10$= +10.000$
+100MW @70$= -80.000$
1st dispatch
40MW
A B
40MW
Limit: 50MW
Limit: 50MW
Net Withdraw: 80MW
Net Injection:80MW
3 node network
A
B
Injection: 120MW
СDemand: 120MW
Withdrawal: 120MW70$/MWh
40MW80MW
40MW
Marginal Cost?
Dispatch with 3 nodes
30$/MWh
30$/MWh
A
B
Injection: 120MW
СDemand: 120MW
Withdrawal: 120MW70$/MWh
40MW80MW
40MW
Dispatch with 3 nodes
30$/MWh
Limit: 500MWLimit: 20MW
Limits
Demand: 120MWWithdrawal: 120MW
A
B
Injection: 120MW
С
Limit: 500MWLimit: 20MW
40MW80MW
40MW
Injection: 60MW
20MW
20MW
60MW30$/MWh 60MWh is shed!
Solution 1?: lower injection
40MW
70$/MWh
30$/MWhLimits
Demand: 120MWWithdrawal: 120MW
A: 40MW
A
B
Injection: 120MW30$/MWh
С
Limit: 500MWLimit: 20MW
70$/MWh
A: 80MW
A: 40MW
Solution 2?: Add counter flow
Inject 60 MW
B: 20MWB: 2
0MW
B: 40MW180MW
A NET: 20MW
Limits
A: 40MW
A
B
Injection: 120MW30$/MWh
С
Limit: 500MWLimit: 20MW
70$/MWh
A: 80MW
A: 40MW
Solution 3: Counter flow & proportional downturning
Inject 60 MW
B: 20MWB: 2
0MW
B: 40MW
Injection: 80MW30$/MWh
A: 53.33 M
W A: 26.67 MW
A: 26.67 MW
Inject 40 MW
B: 13.33 MW
B: 13.3
3 MW
B: 26.67 MWDemand: 120MW
Withdrawal: 180MW120MW
• Up till 60MW from A no problem
A
B
Injection: 60MW30$/MWh
С
Limit: 500MWLimit: 20MW
70$/MWh
A:20MWA:40MW
A: 20MW
Limits
Demand: 120MWWithdrawal: 60MW
A: +⅓ MW
A: 20MW
A
B
Injection: 60MW30$/MWh
С
Limit: 500MWLimit: 20MW
70$/MWh
A: 40MW
A: 20MW
Limits+1 MW
B: + ⅓ MW
+1 MWDemand: 120MW
Withdrawal: 60MW
A:+10 MW
A: 20MW
A
B
Injection: 60MW30$/MWh
С
Limit: 500MWLimit: 20MW
A: 40MW
A: 20MW
Limits+30 MW
B: +10 MW
+30 MW70$/MWhDemand: 120MW
Withdrawal: 60MW
A: 30MW
A: 60MW
B: 20MW
B: 10MW
90MW120MWMarginal Cost? 50$/MWh
• When– A can inject maximally 90MW? – And B increases demand with 10MW
• what is then the MC and AC?
• Nodal & Zonal• Peak-load pricing
Peak-load pricingExample: Transmission interconnector line
ST-MC
Off-peak
Peak
LT-MCPpeak
POff-peak=0
91
Peak-load pricingGives clear economic signals!
ST-MC
Off-peak
Peak
LT-MCPpeak
POff-peak=0
92
ST-MC
Off-peak
Peak
LT-MC
Ppeak
POff-peak=0
Invest in expansion of transmission capacity on the line
Do not invest in expansion
(wait or even remove a line)
Zonal pricing -> averaging
(EU)
Nodal pricing (also Locational Marginal Pricing) -> peak-load pricing
(USA)
Peak-load pricingExample: Transmission interconnector line
ST-MC
Off-peak
Peak
LT-MC
POff-peak
Ppeak
PAVERAGE
94
