A Theoretical And Experimental Investigation For Developing A Methodology For Co/poly-generation Systems / With Special Emphasis On Testing, Energy And Exergy Rating

Bingol, Ekin

01 October 2010

A poly-generation system can be defined as the simultaneous and collocated generation of two or more energy supply types, aimed to maximize the utilization of the thermodynamic potential (efficiency) of the consumed energy resources. A Polygeneration system may involve co-generation (power and heat) or tri-generation (power, heat, and cold) processes and may also be connected to a district energy system. A poly-generation plant reclaims heat in a useful form that would be wasted otherwise in separate electricity and heat (and chilled water in some cases) generating systems. By this way a poly-generation plant provides a variety of benefits including improved efficiency and fuel savings, reduction of the primary energy demand total cost of utility service and unit fuel cost, independency for energy and protection of environment. With the overall efficiencies in the range of 70-90%, poly-generation systems are gaining popularity all around the world. including Turkey. In spite of all their potential benefits and increasing interest for poly-generation systems, there is not yet any rating, testing, metrication and classification guidelines and standards. It is indeed very important to rate the performance and energy savings potential, determine the heat and power outputs, estimate the system efficiency and the ratio of the split of the power produced between thermal and electric. These are the information which are hard to determine since there are not enough common test standards, rating standards and nor consensus-based terminology for combined heat and power systems in the world literature. Even the classification of the cogeneration systems is hardly globalized. Aim of this study is to develop a common procedure with respect to the above shortcomings for testing and rating poly-generation systems under realistic operating conditions with accurate formulae which will help to contribute energy and exergy economy by establishing a robust metrication standard based on new evaluation parameters. This study aims to find a procedure to evaluate a poly-generation system by establishing standard test methods and evaluation tools in terms of parameters like energy and exergy characteristics of thermal and electric loads, temperature demand and power split for determining operational characteristics of the system. This may be achieved by revising and expanding DIRECTIVE 2004/8/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL. A case study is expected to be based on a trigeneration power plant to be received within the framework of the EU FP6 HEGEL Poly-generation project, to be tested at METU, which has a capacity of 145 kW electric and 160 kW useful heat.

TJ Mechanical Engineering. 1-1570

Energy Need Assessment and Preferential Choice Survey o fMatipukur Village in Bangladesh : Energy Need Assessment and Preferential Choice Survey of Rural People in Bangladesh

Akter, Nasrin

January 2015

The aim of this study is to perform a baseline energy survey to understand the existing energy demand and usepattern and to verify the feasibility of a small scale poly-generation project supported by renewable sources ofenergy (biogas based) in a rural area of Bangladesh. A poly-generation solution shall provide multiple outputservices of clean gas, electricity and arsenic free water supply. The project requires using animal dung oragricultural waste to produce biogas and electric energy. The study has analyzed the demand of domesticenergy and water of the village named ‘Matipukur’ in the Jessore district in Bangladesh. The study alsoconsidered available biomass feedstock and energy potential surrounding the village area, as well as the socioeconomicstatus of villagers. The case study included a door to door survey to collect relevant information.Three different economic groups in terms of income scale were investigated throughout the study to obtainbetter insight of the energy-water access situation, requirements and related problems in the village. Almost 98% household of this village relies on biomass for energy due to limited access of modern fuel. Thevillage has various biomass potential in the form of animal dung, fuel wood and agricultural waste which can beused for cooking or serve as the basis for other energy carriers. Kerosene is used for lighting. Among thedifferent fuels, dung meets about 44% of the total demand. The contribution of other fuels for domestic use is24% firewood, 22% agricultural waste, and 2% kerosene. The analytical observation found that the annualaverage energy demand of the village is 8.45 GJ per capita. The share of average demand for cooking and3lighting energy is 8.24 GJ per person/year and 0.21 GJ per person/year respectively. The energy consumptionvaries within different income groups. This study has examined the income per capita, family size, education,agricultural land holding per capita, priorities of their annual expenditure etc. which have direct influence onthe fuel consumption pattern of the household. It could be observed that expenses on energy changes as theincome level increases. About awareness of biogas opportunities and willingness to provide feedstock for apoly generation project, the majority of households answered positively, that is, indicating that they wouldcontribute. Educated respondents showed more positive attitude. Regarding changing of traditional cooking,about 95% of the respondents want to change to a more efficient and reliable cooking system to avoid healthand environmental problems associated with indoor biomass cooking. The study has revealed that only cow dung is not enough to produce clean energy according to demand so theco-digestion method is considered to producing biogas from various energy potentials (animal manure &agricultural waste). The poly-generation system could work with the scenario providing electricity and watersupply for the entire household and cooking gas is limited only for 2/3rd household. Rest 1/3rd household fromlow income group then could be supplied with improve cook stove to meet their daily cooking demand and tominimize indoor pollutions. It is observed that, majority of household has expressed their willingness toprovide raw materials for poly-generation plant though they are using. / SIDA funded research project "Biogas based poly generation in Bangladesh"

Energy

access

biomass

biogas

poly-generation

household

cooking

lighting

drinking water

Bangladesh.

Engineering and Technology

Teknik och teknologier

Energy need assessment and preferential choice survey of rural people in Bangladesh

Ahmed, Hassan

January 2013

This study is a part of a poly generation project which will use animal waste or agricultural waste to produce biogas and will provide cooking gas, electricity and arsenic free clean water for drinking in rural areas of Bangladesh.  The study mainly analyzes the cooking and lighting energy demand of households across different income groups in a village named “Pani Para” in the Faridpur district in Bangladesh and also looks at the potential of biogas in the village. It has been done by adopting case study method and conducting a survey in the village using a questionnaire. Fuel mix across different income groups for meeting their cooking and lighting energy needs have also been studied along with socio-economic situation of the villagers and their preferences to change their current cooking fuel utilization patterns. Various scenarios like variation in fuel consumption patterns, priority of income expenditure and access to fuel with income level have been examined. The study also focuses to analyze the awareness of the villagers about biogas technology and their willingness to contribute for the poly generation project along with the willingness of households to pay for embracing change in current cooking and lighting fuels. Biomass potential i.e. cow dung and agricultural waste is also calculated in the surveyed village along with the production of biogas from the available biomass resources. The scenarios to provide the cooking gas, electricity and clean water through biogas poly generation project from the available resources are also investigated. Analysis reveals that the total energy consumption (cooking and lighting) increases with the increase in the income level among the households. Average household cooking and lighting energy demand by low, medium and high income groups is 8492 kWh/yr, 9789 kWh/yr and 14806 kWh/yr respectively. Cooking energy demand and agricultural waste consumption also show an increasing trend with the increase in land holding size. Among the income expenditure priorities food is one of the most important priorities and energy being less important due to availability of biomass at little or no cost. Awareness of biogas technology among the households and willingness to contribute for the poly generation plant shows an increasing trend with the increase in education level. The study shows that there is a positive response of the villagers for being willing to embrace the change in the current cooking patterns as well as welcoming new technologies that could support such a change. It was found that the cow dung resource in the village is not enough to produce sufficient biogas for the poly generation project. With the incorporation of the agricultural waste with the cow dung, biogas production comes quite close to requirement of the poly generation plant but however could not suffice it completely due to the lack of raw material in the studied village. In that case the scenario of providing electricity and clean water to all the villagers and providing all the three facilities to the 2/3rd of households is investigated. 1/3rd of the low income households then could meet their cooking demands by provision of improved cooking stoves as cooking gas could not be provided to them due to limited feedstock. The study shows that despite of the fact that cooking and lighting energy needs increase with income but there is not much variation in the fuel mix and almost everyone in the village rely on biomass to meet their energy demand. It is because there is very limited access to the modern fuel for cooking and no electricity access in the village, so the households have to rely on the traditional fuels. / <p>KTH School of Industrial Engineering and Management, Department of Energy Technology, Division of Energy and Climate studies</p>

Traditional biomass fuels

energy demand

biogas poly generation

Grameen Shakti

co-generation

cooking and lighting energy.

Engineering and Technology

Teknik och teknologier