Introduction%20to%20the%20EnergyPLAN%20model - PowerPoint PPT Presentation

Title: Introduction%20to%20the%20EnergyPLAN%20model


1
Introduction to the EnergyPLAN model
Aalborg University, September October
2005PhD-course Energy System Analysis I

• Henrik Lund
• Aalborg University
• Denmark

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Content Workshop aproach!!Development
aproach..!!

• 1. (23 August) Introduction to studies made by
  the use of EnergyPLAN. Discussion of participants
  ideas of PhD projects and potential use of the
  model.
• 2. (30 August) Details inside the model. How
  does it work? How are the modelling of specific
  components, units etc? Discussion of
  PhD-projects Strengths and weakness of the
  model?
• The period between 23 August and 5 September
  Participants install the model and make familiar
  with the model and make som preliminary analyses.
• 3. (6 September) Discussion of participants
  analyses. Results, problems, room for
  improvements of the model!!! Etc..

3
www.plan.aau.dk/lund

• Download EnergyPLAN
• Download documentation
• Links to journal articles (results)
• Links to research reports (Danish)

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EnergyPLAN Model 6.0
Input
Output
Distribution Data
Demands Fixed electricity Flexible electricity
District Heating
Market Prices
Electricity
District H.
Wind

• Results
• (Annual, monthly and hour by hour values)
• Heat productions
• Electricity production
• Electricity import export
• Forced electricity surplus production
• Fuel consumption
• Payments from import/export
• CO2 emissions
• Share of RES

Solar
Industrial CHP
Photo Voltaic
RES Wind and PV Capacities (MW) Distribution
Factor Solar Thermal and CSHP (TWh/year)

• Regulation strategy
• 1. Meeting heat demand
• 2. Meeting both heat and electricity demand
• Electricity Market Strategy
• Import/export optimisation
• Critical surplus production
• reducing wind,
• replacing CHP with boiler or heat pump
• Electric heating and/or Bypass

Capacities Efficiencies CHP, Power plant, Heat
Pump, Boiler Heat Storage
Regulation Market prises Multiplication
factor Addition factor Depend factor Marginal
production Cost (Import, export) Stabilisation
demands
Fuel Types of fuel CO2 emission factors Fuel
prices
5
Energy System
Import Export
Wind Power
Photo Voltaic
Electricity Demand
Power Plant
Transport Flexible
CHP unit CSHP unit
Heat Pump
Fuel
Heat Demand
Boiler DH-boiler
Heat Storage
Solar Thermal
6
Energy System 6.2
Water Storage
Wind Power
Import Export
Photo Voltaic
Turbine
Pump
Wave Energy
Electricity Demand
Power Plant
Transport Flexible
Electro- lyser
Heat Pump
CHP unit CSHP unit
Fuel
Heat Demand
Heat Storage
Boiler DH-boiler
Solar Thermal
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Overview

• Initial calculations
• From annual values to hour by hour
• RES modifications
• Market price modifications
• DH production
• Flexible demand
• Optimisation calculations
• Technical optimisation of regulation I, II, III
  or IV accordingly
• Eventual market optimisation
• Improvements by use of Heat storage
• NEW Calculating electricity storage and
  electrolysers
• Reducing critical excess production
• Electrcity market modelling
• Calculating resulting fuel and CO2 outputs

8
From annual values to hour by hour

• Demands (elec. And district heating, eventual
  transport)
• RES (wind and pv etc.)
• Market prices
• Fixed import/export

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RES modifications
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Market price modifications

• pi (DKK/MWh) NPi F Pa
• Facdepend Dtrade

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DH production

• qDHP qi - qsolar - qCSHP

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Flexible demand
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Overview

• Initial calculations
• From annual values to hour by hour
• RES modifications
• Market price modifications
• DH production
• Flexible demand
• Optimisation calculations
• Technical optimisation of regulation I, II, III
  or IV accordingly
• Eventual market optimisation
• NEW Calculating electrolysers
• NEW Calculating electricity storage
• Improvements by use of Heat storage
• Reducing critical excess production
• Electrcity market modelling
• Calculating resulting fuel and CO2 outputs

15
Regulation strategies

• 1. Meeting heat demands
• 2. Meeting both heat and electricity demands
• 3. Like 2 BUT reduce CHP also when is needed for
  stabilisation reasons
• 4. Like 1 BUT meeting triple tariff.

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Limitations

• Stabilisation share
• Minimum CHP 3 level
• Heat pump share of district heating production

17
Eventual market optimisation

• Marginal production costs compared to market
  prices define the production

18
Energy System 6.2
Water Storage
Wind Power
Import Export
Photo Voltaic
Turbine
Pump
Wave Energy
Electricity Demand
Power Plant
Transport Flexible
Electro- lyser
Heat Pump
CHP unit CSHP unit
Fuel
Heat Demand
Heat Storage
Boiler DH-boiler
Solar Thermal
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Electrolyser

• Produce fuel in the case of critical excess
  production
• Heat replace 1. boilers, 2. CHP and 3. heat pumps
  in the relevant DH-group.
• Fuel is used to replace fuel consumption in CHP
  and boilers in the relevant DH-group.

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Electricity storage

• Fill storage when positive critical excess
  production
• Empty storage to replace condensing power plant
  production
• Iteration of storage content untill the content
  in the beginning of the year is the same as in
  the end.

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Heat storage

• In two situations the storage can be loaded
• A Increasing the use of HP in situations with
  electricity export.
• B Moving the electricity production from
  condensing plants, epp to CHP plants
• In two situations the storage can be unloaded
• C Reducing the CHP production in situations with
  electricity export
• D Reducing the boiler production.
• B is secondary to A and D is secondary to C. The
  four loading and unloading cases are used in the
  following order C-A-B-D.

22
Overview

• Initial calculations
• From annual values to hour by hour
• RES modifications
• Market price modifications
• DH production
• Flexible demand
• Optimisation calculations
• Technical optimisation of regulation I, II, III
  or IV accordingly
• Eventual market optimisation
• NEW Calculating electrolysers
• NEW Calculating electricity storage
• Improvements by use of Heat storage
• Reducing critical excess production
• Electrcity market modelling
• Calculating resulting fuel and CO2 outputs

23
Critical Excess production

• 1 Reducing wind production
• 2. Reducing CHP in gr. 2 replacing with boiler
• 3. Reducing CHP in gr. 3 replacing with boiler
• 4. Replacing boiler with electric heating in gr.
  2
• 5. Replacing boiler with electric heating in gr.
  3
• 6. Reducing PV production
• 7. Reducing power plant in combination with wind
  and PV production

24
Electricity Market modelling

• 1. System prices
• 2. Export bottleneck
• 3. Both export and import bottlenecks

25
Resulting fuel and CO2 outputs
26
Results
27
Introduction to the EnergyPLAN model
Aalborg University, September October
2005PhD-course Energy System Analysis I

• Henrik Lund
• Aalborg University
• Denmark