Combined Electricity Production and Thermally Driven Cooling from Municipal Solid Waste

Increasingly intensive efforts are being made to enhance energy systems via augmented introduction of renewable energy along with improved energy efficiency. Resource constraints and sustained high fossil fuel prices have created a new phenomenon in the world market. Enhanced energy security and renewable energy development are currently high on public agenda worldwide for achieving a high standard of welfare for future generations. Biomass and municipal solid waste (MSW) have widely been accepted as important locally-available renewable energy sources offering low carbon dioxide (CO2) emissions. Concerning solid waste management, it has become a critical issue in Southeast Asia since the most popular form for waste disposal still employs open dumping and landfilling. While the need for a complete sustainable energy solution is apparent, solid waste management is also an essential objective, so it makes sense to explore ways in which the two can be joined. Electricity production in combination with energy recovery from flue gases in thermal treatment plants is an integral part of MSW management for many industrialized nations. In Sweden, MSW is considered as an important fuel resource for partially meeting EU environmental targets within cogeneration. However it is normally difficult to justify traditional cogeneration in tropical locations since there is little need for the heat produced. Similarly, MSW-fired cogeneration usually operates with low capacity during non-heating season in Sweden. Therefore, it is very important to find new alternatives for energy applications from waste, such as the implementation of thermally driven cooling processes via absorption cooling in addition to electricity production. The work presented herein concentrates first on an investigation of electricity generation from MSW power plants and various energy applications from waste in tropical urban areas. The potential for various types of absorption chillers driven by MSW power plants for providing both electricity and cooling is of particular interest. Additionally a demonstration and analysis of decentralized thermally driven cooling in district heating network supplied by low temperature heat from a cogeneration of MSW have been conducted. This study aims at developing the best system configuration as well as finding improved system design and control for a combination of district heating and distributed thermally driven cooling. Results show that MSW incineration has the ability to lessen environmental impacts associated with waste disposal, and it can contribute positively towards expanding biomass-based energy production in Southeast Asia. For electricity production, the proposed hybrid dual-fuel (MSW/natural gas) cycles feature attractive electrical efficiency improvements, leading to greenhouse gas emissions reduction. Cogeneration coupled with thermally driven cooling is a solution that holds promise for uniting enhanced sustainability with economic advantages. The system offers great opportunity for primary energy saving, increasing electrical yield and can significantly reduce CO2 emissions per unit of cooling as compared to compression chiller. The demonstration and simulation have also revealed that there is a potential with some modifications and improvements to employ decentralized thermally driven cooling in district heating networks even in temperate regions like Sweden. Thus, expanding cogeneration towards trigeneration can augment the energy supply for summer months in Europe and for year-round cooling in tropical locations.QC 2011040

Slutrapport för EU-projekt Polysmart P22374-1

Följande sammanfattar erfarenheterna inom projektet:- Besparing av primärenergi är väldigt beroende av ett fåtal faktorer där primärenergi faktor för generering av el till nätet är avgörande. I projektet använde man termen ”non-renewable primary energy” där förnybara källor som bioenergi och även sopförbränning har väldigt låga värden. Om man använder den europeiska mixen för elproduktion ger enbartkraftvärme nästan alltid besparing av primär energi. Det samma gäller system där man använder förnybar energi eller sopförbränning. För system med trigenerering som använder fossila bränslen måste man ha både hög andel elproduktion från kraftvärmeaggregatet och relativt hög COP för den värmedrivna kylmaskinen om man ska få en besparing av primärenergi.- Systemen är komplexa och man har lärt sig mycket inom projektet. Dock har man inte kommit så långt som standard systempaket.- Elförbrukning är oftast högre än förväntat och i verklighet högre än specificerat.- Värmesänkan i systemet är en nyckelkomponent som är kritiskt för bra systemprestanda. Mer FoU krävs för att få fram komponenter som lämpar sig väl till sådana system (och som skulle också gynna andra system).- Mätning av systemet med tillhörande analys har behövts för att förbättra systemprestanda, vilket är kopplat till att system är komplexa och att det inte fanns en grundläggande kompetens i början av projektet hos alla partners.- Lovande nischmarknader har identifierats men de kräver förmodligen paketlösningar som inte finns på marknaden än.- Man ska enbart täcka baslasten med trigenereringssystem.- Koppling med fjärrvärme kan fungera bra men leverantören måste acceptera relativt höga returtemperaturer

Thermally driven cooling coupled with municipal solid waste-fired power plant: Application of combined heat, cooling and power in tropical urban areas

Energy recovery from flue gases in thermal treatment plants is an integral part of municipal solid waste (MSW) management for many industrialized nations. Often cogeneration can be employed for both enhancing the plant profitability and increasing the overall energy yield. However, it is normally difficult to justify traditional cogeneration in tropical locations since there is little need for the heat produced. The main objective of this article is to investigate the opportunities and potentials for various types of absorption technologies driven by MSW power plants for providing both electricity and cooling. Results show that cogeneration coupling with thermally driven cooling is sustainably and economically attractive for both electricity and cooling production. The thermally driven cooling provides significant potential to replace electrically driven cooling: such systems are capable of providing cooling output and simultaneously increasing electricity yield (41%). The systems are also capable of reducing the fuel consumption per unit of cooling in comparison with conventional cooling technology: a reduction of more than 1 MWfuel/MWcooling can be met in a small unit. MSW power plant coupled with thermally driven cooling can further reduce CO2 emissions per unit of cooling of around 60% as compared to conventional compression chiller and has short payback period (less than 5 years).MSW incineration Absorption chillers Thermally driven cooling Economic evaluation Greenhouse gas reduction Tropical urban areas