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Amiri, Shahnaz
Publications (10 of 12) Show all publications
Weinberger, G., Amiri, S. & Moshfegh, B. (2021). Investigating techno-economic effects and environmental impacts of energy renovation of residential building clusters on a district heating system. Energy and Buildings, 251, Article ID 111327.
Open this publication in new window or tab >>Investigating techno-economic effects and environmental impacts of energy renovation of residential building clusters on a district heating system
2021 (English)In: Energy and Buildings, ISSN 0378-7788, E-ISSN 1872-6178, Vol. 251, article id 111327Article in journal (Refereed) Published
Abstract [en]

Studying energy renovation of older residential building stocks together with the surrounding district heating (DH) system is essential to fully understand implications from a reduced district heat demand and for involved actors. This study reveals the benefit of integrating the simulation and optimization tools OPERA-MILP, IDA ICE, and MODEST to investigate thoroughly the effect of energy renovation strategies on heat load supply, building and DH system-based life cycle costs (LCCs), primary energy use, and total of direct and indirect CO2 emissions. Energy renovation considered different cluster combinations of slab and tower blocks of a stock of 343 apartment buildings in two Swedish municipalities and strategies for lowest LCC and code compliance. Applied tools were thoroughly validated and verified including heat demand and load duration curves and numerical accuracy. Results with all aggregated clusters and renovation strategy for code compliance showed a reduced combined heat and power production with 35.7 GWh/a (heat) and 6.5 GWh/a (electricity), deceased primary energy use with 36.2 GWh/a and reduction of marginal CO2 emissions with 8.4 kton/a mainly from released biofuels substituting for fossil fuels in power plants, increased CO2 emissions of 0.5 kton/a with electricity production mix, and financial deficit for building owners, energy companies, and industries of respective 44, 33.9, and 2.2 M€/50a.

Place, publisher, year, edition, pages
Elsevier, 2021
Keywords
Building energy simulation, Building LCC optimization, Cluster energy renovation, Cogeneration, District heating, Energy system optimization, Residential buildings, Validation and verification
National Category
Energy Systems Other Civil Engineering
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-36931 (URN)10.1016/j.enbuild.2021.111327 (DOI)000703182600007 ()2-s2.0-85113347148 (Scopus ID)
Available from: 2021-08-20 Created: 2021-08-20 Last updated: 2023-04-03Bibliographically approved
Milić, V., Amiri, S. & Moshfegh, B. (2020). A systematic approach to predict the economic and environmental effects of the cost-optimal energy renovation of a historic building district on the district heating system. Energies, 13(1), Article ID 276.
Open this publication in new window or tab >>A systematic approach to predict the economic and environmental effects of the cost-optimal energy renovation of a historic building district on the district heating system
2020 (English)In: Energies, E-ISSN 1996-1073, Vol. 13, no 1, article id 276Article in journal (Refereed) Published
Abstract [en]

The economic and environmental performance of a district heating (DH) system is to a great extent affected by the size and dynamic behavior of the DH load. By implementing energy efficiency measures (EEMs) to increase a building’s thermal performance and by performing cost-optimal energy renovation, the operation of the DH system will be altered. This study presents a systematic approach consisting of building categorization, life cycle cost (LCC) optimization, building energy simulation and energy system optimization procedures, investigating the profitability and environmental performance of cost-optimal energy renovation of a historic building district on the DH system. The results show that the proposed approach can successfully be used to predict the economic and environmental effects of cost-optimal energy renovation of a building district on the local DH system. The results revealed that the financial gains of the district are between 186 MSEK (23%) and 218 MSEK (27%) and the financial losses for the DH system vary between 117–194 MSEK (5–8%). However, the suggested renovation measures decrease the local and global CO2 emissions by 71–75 metric ton of CO2eq./year (4%) and 3545–3727 metric ton of CO2eq./year (41–43%), respectively. Total primary energy use was decreased from 57.2 GWh/year to 52.0–52.2 GWh/year.

Place, publisher, year, edition, pages
MDPI, 2020
Keywords
LCC optimization, building energy simulation, energy system optimization, energy renovation, historic building district, district heating system
National Category
Civil Engineering
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-31598 (URN)10.3390/en13010276 (DOI)000520425800276 ()2-s2.0-85077997830 (Scopus ID)
Funder
Swedish Energy Agency, P31669-3Swedish Energy Agency, P44335-1
Available from: 2020-01-30 Created: 2020-01-30 Last updated: 2023-08-28Bibliographically approved
Blomqvist, S., Amiri, S., Rohdin, P. & Ödlund, L. (2019). Analyzing the performance and control of a hydronic pavement system in a district heating network. Energies, 12(11), Article ID 2078.
Open this publication in new window or tab >>Analyzing the performance and control of a hydronic pavement system in a district heating network
2019 (English)In: Energies, E-ISSN 1996-1073, Vol. 12, no 11, article id 2078Article in journal (Refereed) Published
Abstract [en]

A hydronic pavement system (HPS) is an alternative method to clear snow and ice, which avoids the use of salt, sand, and fossil fuel in conventional snow clearance, and minimizes the risk of accidents. The aim is to analyze the performance of different control strategies for a 35,000 m2 HPS utilizing heat from a district heating and cooling (DHC) system. The key performance indicators are (1) energy performance of the HPS, and (2) primary energy use, (3) electricity production and (4) greenhouse gas (GHG) emissions from the DHC system. The methodology uses a simulation model of the HPS and an optimization model of the DHC system. Three operational strategies are analyzed: A reference scenario based on the current control strategy, and scenarios where the HPS is shut down at temperatures below −10 ◦C and −5 ◦C. The study shows that the DHC return temperature is suitable for use. By operational strategies, use during peak demand in the DHC system can be avoided, resulting in reduced use of fossil fuel. Moreover, the energy use of the HPS could be reduced by 10% and the local GHG emissions by 25%. The study emphasizes that the HPS may have positive effects on global GHG emissions, as it enables electricity production from renewable resources. 

Place, publisher, year, edition, pages
MDPI, 2019
Keywords
District heating, Energy system modeling, Greenhouse gas emissions, Hydronic pavement system, Primary energy use, Benchmarking, Electric power generation, Fossil fuels, Gas emissions, Pavements, Snow, Current control strategy, District heating and cooling systems, District heating networks, Electricity production, Energy system model, Key performance indicators, Pavement systems, Greenhouse gases
National Category
Energy Systems
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-30549 (URN)10.3390/en12112078 (DOI)000472635900045 ()2-s2.0-85066765422 (Scopus ID)
Funder
Swedish Agency for Economic and Regional Growth
Available from: 2019-08-22 Created: 2019-08-22 Last updated: 2023-08-28Bibliographically approved
Blomqvist, S., La Fleur, L., Amiri, S., Rohdin, P. & Ödlund, L. (2019). The Impact on System Performance When Renovating a Multifamily Building Stock in a District Heated Region. Sustainability, 11(8), Article ID 2199.
Open this publication in new window or tab >>The Impact on System Performance When Renovating a Multifamily Building Stock in a District Heated Region
Show others...
2019 (English)In: Sustainability, E-ISSN 2071-1050, Vol. 11, no 8, article id 2199Article in journal (Refereed) Published
Abstract [en]

In Sweden, 90% of multifamily buildings utilize district heat and a large portion is in need of renovation. The aim is to analyze the impact of renovating a multifamily building stock in a district heating and cooling system, in terms of primary energy savings, peak power demands, electricity demand and production, and greenhouse gas emissions on local and global levels. The study analyzes scenarios regarding measures on the building envelope, ventilation, and substitution from district heat to ground source heat pump. The results indicate improved energy performance for all scenarios, ranging from 11% to 56%. Moreover, the scenarios present a reduction of fossil fuel use and reduced peak power demand in the district heating and cooling system ranging from 1 MW to 13 MW, corresponding to 4–48 W/m2 heated building area. However, the study concludes that scenarios including a ground source heat pump generate significantly higher global greenhouse gas emissions relative to scenarios including district heating. Furthermore, in a future fossil-free district heating and cooling system, a reduction in primary energy use will lead to a local reduction of emissions along with a positive effect on global greenhouse gas emissions, outperforming measures with a ground source heat pump.

Keywords
district heating, multifamily buildings, renovation, primary energy use, energy system modeling, greenhouse gas emissions
National Category
Civil Engineering
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-31996 (URN)10.3390/su11082199 (DOI)
Available from: 2020-03-05 Created: 2020-03-05 Last updated: 2022-02-10Bibliographically approved
Amiri, S. & Weinberger, G. (2018). Increased cogeneration of renewable electricity through energy cooperation in a Swedish district heating system - A case study. Renewable energy, 116, 866-877
Open this publication in new window or tab >>Increased cogeneration of renewable electricity through energy cooperation in a Swedish district heating system - A case study
2018 (English)In: Renewable energy, ISSN 0960-1481, E-ISSN 1879-0682, Vol. 116, p. 866-877Article in journal (Refereed) Published
Abstract [en]

The present study of the district heating (DH) system in the city of Kisa, Sweden, shows how, through energy cooperation with a nearby sawmill and paper mill, a local energy company contributes to energy-efficient DH and cost-effective utilization of a new biofuel combined heat and power (CHP) plant. Cases of stand-alone and integrated energy systems are optimized with the linear program MODEST. The European power market is assumed to be fully deregulated. The results show clear advantages for the energy company to cooperate with these industries to produce heat for DH and process steam for industry. The cooperating industries gain advantages from heat and/or biofuel by-product supply as well. The opening to use a biofuel CHP plant for combined heat supply results in cogenerated electricity of almost 29 GWh/a with an increased biofuel use of 13 GWh/a, zero fuel oil use and CO2 emission reductions of 25,800 tons CO2/a with coal-condensing power plant on the margin and biofuel as limited resource. The total system cost decreases by −2.18 MEUR/a through extended cooperation and renewable electricity sales. The sensitivity analysis shows that the profitability of investing in a biofuel CHP plant increases with higher electricity and electricity certificate prices.

Keywords
Renewable electricity; Biofuel; Energy cooperation; District heating; CHP; CO2 emission
National Category
Energy Systems
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-25460 (URN)10.1016/j.renene.2017.10.003 (DOI)000416188200077 ()2-s2.0-85031893536 (Scopus ID)
Projects
A project for development of Sustainable Clean Wood Energy in the Central Baltic region
Note

Funding agencies:

Östergötland County Administrative Board  grant no. 304-1677-2012

Linköping University  

University of Gävle  

Available from: 2017-10-25 Created: 2017-10-25 Last updated: 2023-04-03Bibliographically approved
Weinberger, G., Amiri, S. & Moshfegh, B. (2017). On the benefit of integration of a district heating system with industrial excess heat: an economic and environmental analysis. Applied Energy, 191, 454-468
Open this publication in new window or tab >>On the benefit of integration of a district heating system with industrial excess heat: an economic and environmental analysis
2017 (English)In: Applied Energy, ISSN 0306-2619, E-ISSN 1872-9118, Vol. 191, p. 454-468Article in journal (Refereed) Published
Abstract [en]

Energy-related cooperation using industrial excess heat (IEH) in district heating (DH) networks shows economic and environmental benefits. A rarely investigated approach is the energy cooperation which incorporates a jointly operated CHP plant also producing process steam for nearby industry. The present study aims to evaluate economic and environmental effects on the Hofors DH system with jointly operated CHP plant when the nearby steel mill extends the supply of recovered IEH. Various IEH supply opportunities with different capacities of hot water and steam were designed and compared with existing IEH utilization, plant heat and electricity production and DH system performance. The energy system model MODEST is used for cost-optimization. A parametric study is used to analyze influences of increasing IEH cost and fluctuating electricity prices. The results show advantages for the DH system to utilize IEH for deliveries of DH and process steam and the cogeneration of electricity. Economic and environmental benefits are decreased total system cost (-1.67 MEUR/a), less use of fuels and electricity, and reduced CO2 emissions with a maximal reachable amount of 28,200 ton/a when the use of biofuel is assumed as limited resource and the substituted marginal electricity production is based on coal condensing power plants. The results also show that industrial steam is a preferred heat supply source as long as the steam cost is below the alternative heat production cost, irrespective of the electricity price. While the cost-effective utilization of industrial hot water for DH is more sensitive and affected by a beneficial CHP production based on higher electricity price segments, it is also shown that utilization of continuously supplied industrial hot water is limited during seasons of low DH demand.

Keywords
CHP, MODEST, Marginal electricity, System cost, Energy use, CO2 emission
National Category
Energy Systems
Research subject
Sustainable Urban Development
Identifiers
urn:nbn:se:hig:diva-23746 (URN)10.1016/j.apenergy.2017.01.093 (DOI)000395963500036 ()2-s2.0-85012164014 (Scopus ID)
Projects
Ett nytt kylningskoncept för att ta till vara industriellt överskottsvärme från heta kroppar; HIG-FORSK 2012/66
Funder
Swedish Energy Agency
Note

The work has been carried out as part of a project with a new cooling concept in the steel industry, which was financed by the Swedish Energy Agency, the companies Varmevarden AB (Hofors Energi AB), Ovako AB and the Clean Production Center. All companies and participants are greatly acknowledged for their support and contributions.

Available from: 2017-03-14 Created: 2017-03-14 Last updated: 2023-04-03Bibliographically approved
Amiri, S. (2013). Economic and Environmental Benefits of CHP-based District Heating Systems in Sweden. (Doctoral dissertation). Linköping: Linköping University Electronic Press
Open this publication in new window or tab >>Economic and Environmental Benefits of CHP-based District Heating Systems in Sweden
2013 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Future energy systems and thus the climate are affected by many factors, such as energy resources, energy demand, energy policy and the choice of energy technologies. Energy systems of the future are facing three main challenges; the steady growth of global energy demand, the energy resource depletion, as well as the increasing emissions of carbon dioxide (CO2) and other greenhouse gases and their impact on climate change. To meet the mentioned challenges with sustainability in mind, actions that increase energy efficiency and choosing an energy-efficient energy system which is cost efficient will be essential. Combined heat and power (CHP) plants and district heating and cooling could contribute greatly to increased system efficiency by using energy otherwise wasted.

The aim of this study is to increase the understanding of how CHP-based district heating and cooling systems using different primary energy sources can contribute to more cost-efficient energy systems, which reduce global CO2 emissions, and to highlight the impact of some important parameters and measures on Swedish municipal district heating systems. An important assumption in this study is the estimation of CO2 emissions from electricity production, which is based on marginal electricity perspectives. In the short term, the marginal electricity is assumed to come from coal-fired condensing power plants while in the long term it consists of electricity produced by natural gas-fired combined cycle condensing power plants. This means that the local electricity production will replace the marginal electricity production. The underlying assumption is an ideal fully deregulated European electricity market where trade barriers are removed and there are no restrictions on transfer capacity.

The results show that electricity generation in CHP plants, particularly in higher efficiency combined steam and gas turbine heat and power plants using natural gas, can reduce the global environmental impact of energy usage to a great extent. The results confirm, through the scenarios presented in this study, that waste as a fuel in CHP-based district heating systems is fully utilised since it has the lowest operational costs. The results also show how implementation of a biogas-based CHP plant in a biogas system contributes to an efficient system, as well as lowering both CO2 emissions and system costs. The results show that replacing electricity-driven (e.g. compression) cooling by heat-driven cooling using district heating (e.g. absorption chillers) in a CHP system is a cost-effective and climate friendly technology as electricity consumption is reduced while at the same time the electricity generation will be increased. The results of the study also show that there is potential to expand district heating systems to areas with lower heat density, with both environmental and economic benefits for the district heating companies.

The results reveal that the operation of a studied CHP-based district heating system with an imposed emission limit is very sensitive to the way CO2 emissions are accounted, i.e., local CO2 emissions or emissions from marginal electricity production. The results show how the electricity production increases in the marginal case compared with the local one in order to reduce global CO2 emissions. The results also revealed that not only electricity and fuel prices but also policy instruments are important factors in promoting CHP-based district heating and cooling systems. The use of electricity certificates has a large influence for the introduction of biogas-based cogeneration. Another conclusion from the modelling is that present Swedish policy instruments are strong incentives for cogeneration with similar impact as applying external costs.

Abstract [sv]

Framtidens energisystem och därmed även klimatet påverkas av många faktorer, såsom energitillgångar, efterfrågan på energi, energipolicy och valet  av energitekniska lösningar. De framtida energisystemen står inför tre viktiga utmaningar: den ständigt växande efterfrågan på energi i världen, problemet med minskande energitillgångar samt den ökande koldioxidhalten i atmosfären och utsläppen av andra växthusgaser och deras påverkan på klimatförändring. Det blir alltmer angeläget att möta de nämnda utmaningarna med hållbarhetsbegreppet i åtanke, att agera för att öka energieffektiviteten och att välja ett energieffektivt energisystem som också är kostnadseffektivt. Fjärrvärme och fjärrkyla baserade på kraftvärme (CHP) kan i hög grad bidra till ökad effektivitet genom användning av energi som annars skulle gå till spillo.

Syftet med denna studie är att öka förståelsen för hur CHP-baserad fjärrvärme och fjärrkyla som använder olika energikällor kan bidra till mer kostnadseffektiva energisystem som även ger minskade globala koldioxidutsläpp samt att belysa effekterna av vissa viktiga parametrar för svenska fjärrvärmesystem. Ett viktigt antagande i denna studie är beräkningarna av koldioxidutsläppen från elproduktion som är baserade på marginalelsperspektiv. På kort sikt antas marginalelen komma från koleldade kondenskraftverk, medan den på lång sikt utgörs av el som produceras av naturgas i gaskombi-kondenskraftverk. I beräkningarna antas den lokala elproduktionen ersätta marginalelsproduktionen. Det underliggande antagandet är en ideal, helt avreglerad, europeisk elmarknad där handelshindren är borta och det inte finns några begränsningar i överföringskapaciteten.

Resultaten visar att elproduktion i kraftvärmeverk, speciellt i högeffektiva kraftvärmeverk med en kombination av ång- och gasturbiner med naturgas, kan minska den globala miljöpåverkan av energianvändningen avsevärt. Resultaten bekräftar också, genom de scenarier som presenteras i denna studie, att avfall utnyttjas fullt ut som bränsle i kraftvärmebaserade fjärrvärmesystem eftersom det har de lägsta driftskostnaderna. Resultaten visar också hur införande av ett biogasbaserat kraftvärmeverk i ett biogassystem bidrar till ett effektivt system för att minska koldioxidutsläppen och systemkostnaderna. Resultaten visar att det är kostnadseffektivt och klimatvänligt att byta ut eldrivna kompressorkylmaskiner mot värmedrivna absorptionskylmaskiner i ett CHP-system eftersom elanvändningen minskas och elproduktionen samtidigt kommer att öka. Resultaten av studien visar också att det finns potential att bygga ut fjärrvärmesystem till områden med lägre värmetäthet med både miljövinster och ekonomiska fördelar för fjärrvärmeföretagen.

Resultaten visar att driften av ett studerat CHP-baserat fjärrvärmesystem där olika gränsvärden för utsläpp införs är mycket känsligt för hur koldioxidutsläppen redovisas, d v s som lokala koldioxidutsläpp eller utsläpp från marginalel. Resultatet visar hur elproduktionen ökar i marginalelsfallet jämfört med det lokala fallet för att minska de globala koldioxidutsläppen. Resultaten visade också att inte bara el- och bränslepriserna, utan också styrmedlen är viktiga för att främja kraftvärmebaserad fjärrvärme och fjärrkyla. Elcertifikat har t ex stor inverkan på införandet av biogasbaserad kraftvärme. En annan slutsats från modelleringarna är att de styrmedel som finns i dagens Sverige utgör starka incitament för kraftvärme och har en liknande effekt som att använda externa kostnader.

Place, publisher, year, edition, pages
Linköping: Linköping University Electronic Press, 2013. p. 108
Series
Linköping Studies in Science and Technology. Dissertations, ISSN 0345-7524 ; 1524
National Category
Energy Systems
Identifiers
urn:nbn:se:hig:diva-18915 (URN)978-91-7519-604-6 (ISBN)
Public defence
2013-06-10, C3, C-huset, Campus Valla, 10:15 (English)
Opponent
Supervisors
Available from: 2015-02-04 Created: 2015-02-04 Last updated: 2021-10-04Bibliographically approved
Amiri, S., Henning, D. & Karlsson, B. G. (2013). Simulation and introduction of a CHP plant in a Swedish biogas system. Paper presented at 11th World Renewable Energy Congress and Exhibition, September 25-30, 2010, Abu Dhabi, UAE. Renewable energy, 49, 242-249
Open this publication in new window or tab >>Simulation and introduction of a CHP plant in a Swedish biogas system
2013 (English)In: Renewable energy, ISSN 0960-1481, E-ISSN 1879-0682, Vol. 49, p. 242-249Article in journal (Refereed) Published
Abstract [en]

The objectives of this study are to present a model for biogas production systems to help achieve a more cost-effective system, and to analyse the conditions for connecting combined heat and power (CHP) plants to the biogas system. The European electricity market is assumed to be fully deregulated. The relation between connection of CHP. increased electricity and heat production, electricity prices, and electricity certificate trading is investigated. A cost-minimising linear programming model (MODEST) is used. MODEST has been applied to many energy systems, but this is the first time the model has been used for biogas production. The new model, which is the main result of this work, can be used for operational optimisation and evaluating economic consequences of future changes in the biogas system. The results from the case study and sensitivity analysis show that the model is reliable and can be used for strategic planning. The results show that implementation of a biogas-based CHP plant result in an electricity power production of approximately 39 GW h annually. Reduced system costs provide a profitability of 46 MSEK/year if electricity and heat prices increase by 100% and electricity certificate prices increase by 50%. CO2 emission reductions up to 32,000 ton/year can be achieved if generated electricity displaces coal-fired condensing power.

Place, publisher, year, edition, pages
Oxford: PERGAMON-ELSEVIER SCIENCE, 2013
Keywords
Biogas system, CO2 emissions, Energy systems optimisation, Combined heat and power plant, Marginal electricity
National Category
Energy Systems Renewable Bioenergy Research
Identifiers
urn:nbn:se:hig:diva-17865 (URN)10.1016/j.renene.2012.01.022 (DOI)000309902000051 ()2-s2.0-84866561127 (Scopus ID)
Conference
11th World Renewable Energy Congress and Exhibition, September 25-30, 2010, Abu Dhabi, UAE
Available from: 2014-11-09 Created: 2014-11-09 Last updated: 2021-10-04Bibliographically approved
Amiri, S. & Moshfegh, B. (2010). Possibilities and consequences of deregulation of the European electricity market for connection of heat sparse areas to district heating systems. Applied Energy, 87(7), 2401-2410
Open this publication in new window or tab >>Possibilities and consequences of deregulation of the European electricity market for connection of heat sparse areas to district heating systems
2010 (English)In: Applied Energy, ISSN 0306-2619, E-ISSN 1872-9118, Vol. 87, no 7, p. 2401-2410Article in journal (Refereed) Published
Abstract [en]

The objective of the study is to analyse the conditions for connection of residential buildings in heat sparse areas to district heating systems in order to increase electricity production in municipal combined heat and power plants. The European electricity market has been assumed to be fully deregulated. The relation between connection of heat sparse areas, increased electricity and heat production as well as electricity prices, fuel prices and emissions rights is investigated. The results of the study show that there is potential to expand the district heating market to areas with lower heat concentrations in the cities of Gavle, Sandviken and Borlange in Sweden, with both economic and environmental benefits. The expansion provides a substantial heat demand of approximately 181 GWh/year, which results in an electricity power production of approximately 43 GWh/year. Since the detached and stand-alone houses in the studied heat sparse areas have been heated either by oil boiler or by direct electricity, connection to district heating also provides a substantial reduction in emissions of CO(2). The largest reductions in CO(2) emissions are found to be 211 ktonnes/year assuming coal-fired condensing power as marginal electricity production. Connection of heat sparse areas to district heating decrease the system costs and provide a profitability by approximately 22 million EURO/year for the studied municipalities if the price of electricity is at a European level, i.e. 110 EURO/MWh. Sensitivity analysis shows, among other things, that a strong relation exists between the price of electricity and the profitability of connecting heat sparse areas to district heating systems.

Keywords
Combined heat and power, Heat sparse areas, CO(2) emissions, District heating, Deregulated electricity market
National Category
Energy Engineering
Identifiers
urn:nbn:se:hig:diva-10271 (URN)10.1016/j.apenergy.2010.02.002 (DOI)000278675100034 ()2-s2.0-77953157422 (Scopus ID)
Available from: 2011-09-21 Created: 2011-09-21 Last updated: 2021-10-04Bibliographically approved
Amiri, S., Trygg, L. & Moshfegh, B. (2009). Assessment of the natural gas potential for heat and power generation in the County of Östergötland in Sweden. Energy Policy, 37(2), 496-506
Open this publication in new window or tab >>Assessment of the natural gas potential for heat and power generation in the County of Östergötland in Sweden
2009 (English)In: Energy Policy, ISSN 0301-4215, E-ISSN 1873-6777, Vol. 37, no 2, p. 496-506Article in journal (Refereed) Published
Abstract [en]

The aim of this study is to investigate the potential use of natural gas for heat and power production for the municipality of Linkoping, Norrkoping and Finspang in the County of Ostergotland, Sweden. The results of the study revealed that these three municipalities with the present heating demand can convert 2030 GWh/year of the present fuel mixed to natural gas. The expansion of natural gas provides the possibility to increase the electricity generation with approximately 800 GWh annually in the County of Ostergotland. The global emissions of CO(2) reduce also by approximately 490 ktonne/year by assuming the coal condensing power plant as the marginal power plant. The total system cost decreases by 76 Mkr/year with the present electricity price which varies between 432 and 173 SEK/MWh and with 248 Mkr/year if the present electricity price increases to 37% which is approximately corresponding to European electricity prices. Sensitivity analysis is done with respect to the different factors such as price of electricity, natural gas, etc. The findings show that increased price of electricity and increased district heating demand increases the profitability to convert to natural gas using CHP plant. (C) 2008 Elsevier Ltd. All rights reserved.

Keywords
Natural gas; CO(2) emissions; Combined heat and power
National Category
Energy Engineering
Identifiers
urn:nbn:se:hig:diva-10244 (URN)10.1016/j.enpol.2008.09.080 (DOI)000263208500012 ()2-s2.0-58149119592 (Scopus ID)
Available from: 2011-09-21 Created: 2011-09-21 Last updated: 2021-10-04Bibliographically approved
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