Rural electrification under liberal reforms: the case of Peru

Liberal reform programmes in developing countries were not designed with the need to extend electricity supplies to rural areas. This paper focuses on the Peruvian experience, examining the impact of electricity reform policies on the characteristics of rural electrification. In rural areas, electrification levels have traditionally been the lowest in the country – making them less or non-profitable for private firms. Only in 2002 did the government introduce a specific Rural Electrification Law, which was intended to promote electrification within the context of a liberalised market. This paper draws upon an analysis of both this piece of legislation and stakeholder interviews, indicating that there exists a need to look further into the evolving relationship between the private and public sectors and how it affects the rural poor. This study forms part of the RESURL international research project on renewable energy for sustainable rural livelihoods in developing countries, funded by the UK Government's Department for International Development (DfID).     

Solar- und Windenergie zum Pumpen von Wasser

Water pumping by means of wind and solar energy becomes more and more attractive by reason of increasing energy prices. Water supply for remote villages especially in developing countries needs hydraulic energy of about 1 to 50 kWh per day. The use of renewable energies like solar and wind seems to be technically successfull and has a good chance to be competitive with conventional energy sources like diesel or electricity in regions with mean wind speeds above 4–5 m/s or high insolation of about 5 kWh/day annual average.     

Simulation of a 100-MW solar-powered thermo-chemical air separation system combined with an oxy-fuel power plant for bio-energy with carbon capture and storage (BECCS)

The combination of concentrated solar power–chemical looping air separation (CSP-CLAS) with an oxy-fuel combustion process for carbon dioxide (CO₂) capture is a novel system to generate electricity from solar power and biomass while being able to store solar power efficiently. In this study, the computer program Advanced System for Process Engineering Plus (ASPEN Plus) was used to develop models to assess the process performance of such a process with manganese (Mn)-based oxygen carriers on alumina (Al₂O₃) support for a location in the region of Seville in Spain, using real solar beam irradiance and electricity demand data. It was shown that the utilisation of olive tree prunings (Olea europaea) as the fuel—an agricultural residue produced locally—results in negative CO₂ emissions (a net removal of CO₂ from the atmosphere). Furthermore, it was found that the process with an annual average electricity output of 18 MW would utilise 2.43% of Andalusia’s olive tree prunings, thereby capturing 260.5 k-tonnes of CO₂, annually. Drawbacks of the system are its relatively high complexity, a significant energy penalty in the CLAS process associated with the steam requirements for the loop-seal fluidisation, and the gas storage requirements. Nevertheless, the utilisation of agricultural residues is highly promising, and given the large quantities produced globally (~?4 billion tonnes/year), it is suggested that other novel processes tailored to these fuels should be investigated, under consideration of a future price on CO₂ emissions, integration potential with a likely electricity grid system, and based on the local conditions and real data.

     

Modeling increased demand of energy for air conditioners and consequent CO2 emissions to minimize health risks due to climate change in India

Developing countries situated mostly in latitudes that are projected for the highest climate change impact in the twenty-first century will also have a predictable increase in demand on energy sources. India presents us with a unique opportunity to study this phenomenon in a large developing country. This study finds that climate adaptation policies of India should consider the significance of air conditioners (A/Cs) in mitigation of human vulnerability due to unpredictable weather events such as heat waves. However, the energy demand due to air conditioning usage alone will be in the range of an extra ～750,000 GWh to ～1,350,000 GWh with a 3.7 °C increase in surface temperatures under different population scenarios and increasing incomes by the year 2100. We project that residential A/C usage by 2100 will result in CO₂ emissions of 592 Tg to 1064 Tg. This is significant given that India's total contribution to global CO₂ emissions in 2009 was measured at 1670 Tg and country's residential and commercial electricity consumption in 2007 was estimated at 145,000 GWh.     

Renewable energy resources and technologies in Nigeria: present situation, future prospects and policy framework

Nigeria is endowed with abundant energy resources, both conventional and renewable, whichprovide her with immense capacity to develop an effective national energy plan. However, introduction of renewable energyresources into the nation's energy mix have implications on itsenergy budget. The national energy supply system has been projected intothe future using MARKAL, a large scale linear optimization model.However, this model may not be absolutely representative of the highlynon-linear future of renewable energy. Results of the model reveal that under onlya least cost constraint, only large hydro power technology is the prominentcommercial renewable energy technology in the electricity supply mix of thecountry. Despite the immense solar energy potentials available, solar electricity generation is attractive only under severeCO2 emissions mitigation of the nation's energy supply system. Similarly, the penetration of small-scale hydro power technology in theelectricity supply mix is favoured only under CO₂ emissionsconstraints. Due to economy of scale, large hydropower technology takes the lion share of all the commercial renewableenergy resources share for electricity generation under any CO₂emissions constraint. These analyses reveal that some barriers exist to thedevelopment and penetration of renewable energy resources electricity production in Nigeria's energy supplysystem. Barriers and possible strategies to overcome them arediscussed. Intensive efforts and realistic approachtowards energy supply system in the country will have to be adopted inorder to adequately exploit renewable energy resources and technologiesfor economic growth and development.     

Carbon dioxide direct air capture for effective climate change mitigation based on renewable electricity: a new type of energy system sector coupling

Pathways for achieving the 1.5–2 °C global temperature moderation target imply a massive scaling of carbon dioxide (CO₂) removal technologies, in particular in the 2040s and onwards. CO₂ direct air capture (DAC) is among the most promising negative emission technologies (NETs). The energy demands for low-temperature solid-sorbent DAC are mainly heat at around 100 °C and electricity, which lead to sustainably operated DAC systems based on low-cost renewable electricity and heat pumps for the heat supply. This analysis is carried out for the case of the Maghreb region, which enjoys abundantly available low-cost renewable energy resources. The energy transition results for the Maghreb region lead to a solar photovoltaic (PV)-dominated energy supply with some wind energy contribution. DAC systems will need the same energy supply structure. The research investigates the levelised cost of CO₂ DAC (LCOD) in high spatial resolution and is based on full hourly modelling for the Maghreb region. The key results are LCOD of about 55 €/t_CO2 in 2050 with a further cost reduction potential of up to 50%. The area demand is considered and concluded to be negligible. Major conclusions for CO₂ removal as a new energy sector are drawn. Key options for a global climate change mitigation strategy are first an energy transition towards renewable energy and second NETs for achieving the targets of the Paris Agreement.

     

Potential of surplus biomass gasifier based power generation: A case study of an Indian state Rajasthan

Facing the finiteness of fossil fuels and its associated environmental problems, new prospects to cover energy demand are urgently required. Energy from surplus biomass can support an essential contribution to a sustainable energy generation. This paper deals with a case study of surplus biomass available in the Indian state Rajasthan. About 1275 MW electrical power is possible to generate through biomass gasifier based power generation plant through surplus biomass available in Rajasthan. About 1656 tonnes of CO₂ can be saved annually by installation of 1 MW biomass gasifier based power plant. The techno economic parameter like net present worth, cost benefit ratio and pay back period are also carried out for this route of power generation and these are about 1.18 million US$, 1.42 and 8 years and 2 months respectively.     

Feasibility of husk-fuelled steam engines as prime mover of grid-connected generators under the Thai very small renewable energy power producer (VSPP) program

Rice husk generated as a by-product of rice mill processes can be utilized as an energy source for husk-fuelled rice mills. The economic evaluation of the investment of husk-fuelled steam engine rice mills, which generate mechanical energy for the direct driving of milling equipments, has previously been presented in literature. It was reported that for some particular conditions of rice mill, the investment of husk-fuelled steam engine as energy-saving technology is financially feasible. Since May 2002, electricity distributors in Thailand have allowed renewable energy producers up to 1 MW to connect their generators to the grid in order to sell surplus electricity to the grid. This arrangement creates more income opportunities for husk-fuelled steam engine owners to generate not only mechanical power for rice milling processes, but also surplus electricity for feeding onto the grid. The objective of this study is to investigate the financial feasibility of the investment in a husk-fuelled steam engine system which drives grid-connected electrical generators, reduces rice mill demand and electricity and sells surplus electricity to the grid. The technical and economic data for rice mill sizes 35, 45, 60, 95 and 120 t/d presented in this study show that the husk-fuelled steam engine system with grid-connected generators improves the economic performance of applying the system solely for the largest 120 t/d rice mills. However, the conventional husk-fuelled steam engine without electric generator gives a better economic performance of the rice mills sizes from 45 to 95 t/d.     

Energy sector reform in Eritrea: initiatives and implications

The Government of Eritrea gave priority status to the energy sector immediately after the country's independence in May 1991, as manifested by the rapid improvement in electricity and oil supplies. Electricity generation capacity has increased from a total of 30 MW in 1991 to over 130 MW at present. The lengths of transmission and distribution lines have similarly increased from 150 km to 400 km and from 800 to 1300 km respectively. However, as in most Sub-Saharan Africa, this public utility is characterised by inefficient managerial, technical and financial performances, an inability to mobilize the funds needed for expansion, low repair and maintenance capacity, inappropriate tariff rates, and inadequate revenue collection mechanisms. This has led the government to take appropriate reform measures in recent years, including the restructuring of the Eritrea Electric Corporation (EEC) to operate on commercial principles, setting tariffs based on real costs and reasonable profits, effective collection of revenues, the minimization of wastage and loss in the delivery of energy services, facilitating the private sector participation, and ring-fencing the interests of the poor by setting up a Rural Electrification Fund. A Regulatory body has been established to enforce these reform measures. Recognising the role of modern energy in poverty reduction and achieving the Millennium Development Goals (MDGs), the Government with the support of its development partners is expanding energy services to rural areas in an innovative manner. The Government's commitment to diversify energy sources is exemplified by its agreement with the Global Environment Facility (GEF) to share the costs of an on-going pilot wind energy project. It has also established an Energy Research and Training Centre to promote the application of renewable energies and improved biomass stoves throughout Eritrea.     

How China’s current energy pricing mechanisms will impact its marginal carbon abatement costs?

Economic and social costs and benefits are critical factors affecting greenhouse gas abatement activities. Recognizing that energy prices are one of the most important factors influencing abatement costs, this study improved the basic China Energy and Environmental Policy Analysis (CEEPA) model by introducing a current energy pricing mechanism for China. The improved model was applied to generate marginal abatement cost (MAC) curves for China including the current energy pricing mechanism and to analyze MACs for the whole country and main abatement sectors in China under different energy pricing mechanisms. The results show that China MACs are sensitive to pricing mechanisms for electricity and refined oil. Ignoring the current regulation of these prices will lead to MAC underestimation, and price liberalization of these two energy sources could lead to a decrease in China MACs. Under a 50 % emission reduction target, if the electricity price regulation is ignored, the China MAC is underestimated by almost 16 %. Energy pricing reforms will lead to variations in sectoral abatement costs and overall abatement potential, and these impacts are projected to be large in the electricity sector. Under a 50 % reduction target, if the electricity price regulation is liberalized, MAC for the electricity sector nearly will decrease 50 %.     

Minimizing greenhouse gas emissions through the application of solar thermal energy in industrial processes

The analysis of industrial energy usage indicates that low temperature processes (20 ≈ 200 °C) are used in nearly all industrial sectors. In principle there is the potential to use solar thermal energy in these lower temperature processes thus, reducing the environmental impact of burning fossil fuels. Using the model of an Austrian dairy plant, this research investigated the potential for, and the economic viability of, using solar energy heat processes in industry.Some industrial sectors such as food, chemistry, plastic processing, textile industry, building materials industry and business establishments can be identified as potential sectors for the application of solar energy heat processes. When assessing the (economic) feasibility of solar thermal energy, the investigation of these industries’ energy systems has to focus on an integrated analysis of cooling and heating demands and to take into account competing technologies. Amongst these are heat integration, cogeneration, new technologies and heat pumps. Pinch analysis was used to investigate industrial energy systems and heat integration possibilities and proved to be a viable tool. Working from the basis of energy balances, Sankey diagrams, pinch analysis and environmental cost accounting, a newly developed investigation tool was applied in the case study of an Austrian dairy plant. This enabled a fast optimization of the system. Two different options for the integration of solar thermal energy into the production line were calculated, option 1 with a solar field of 1000 m² and option 2 with a solar field of 1500 m². Natural gas savings of 85,000 for option 1 and 109,000 m³/a for option 2 can be achieved, resulting in a reduction of 170 tons of CO₂ per year, or 218 tons for options 1 and 2 respectively. Based upon option 1, return on investment is realised after less than three years of implementation. This research thus, indicates promising technical and economical feasibility of using solar thermal energy for industrial processes and provides an important step towards sustainable zero emission production in industry.     

Development of alternative energy sources for GHG emissions reduction in the textile industry by energy recovery from cotton ginning waste

The agricultural sector and primarily its cotton subsector are of great importance for Greece, due to the intensive agricultural activities. The wastes from cotton ginning plants are also considerable and can be valorized for bioenergy production. The substitution of conventional by green fuels, which can be produced from cotton ginning wastes, is a step towards: (a) economic and environmental sustainability for the textile industry and (b) the development of alternative energy supplies, contributing to the reduction of GHG emissions. Furthermore, it consists an especially attractive opportunity to invest in rural areas. The present paper concerns the feasibility study for energy recovery from cotton ginning waste with GHG emissions reduction in a textile plant located in Northern Greece. The aim was to replace part of heavy fuel oil used for the thermal needs of the plant by biomass. The results showed that the most economically interesting energy option for a bioenergy unit in the above textile plant is 5 MW for the coverage of the 52% of the plant's thermal requirements.     

浅析青岛太阳能光伏发电发展的方向及推广对策

太阳能光伏发电是可再生能源应用的主要方向之一。作为适宜发展太阳能光伏发电的地区,青岛市政电网覆盖区外的诸多海岛具有较好的光伏发电推广应用前景;在市政电网成型地区,道路照明等公共设施用电、新建住宅小区、机关事业单位以及重点用能单位也是具有推广光伏发电的潜力。然而,目前存在的技术瓶颈、激励政策缺乏以及并网发电手续繁琐等因素制约了光伏发电的应用。通过推动光伏发电技术进步及产业发展,并在政策法规以及经济上给予更多鼓励支持,才能促进太阳能光伏发电快速、健康发展。     

Co-production of heat and power: an anchor tenant of a regional industrial ecosystem

The resource basis of industrial energy production is still, to a large extent, in non-renewable fossil fuels, the use of which creates emissions that the ecosystem has difficulty in tolerating. The goal of industrial ecology is to substitute the non-renewable stocks with renewable flows. In this paper, a regional industrial ecosystem that relies on a power plant as its key organisation, as an anchor tenant, is considered in the context of energy production and consumption. The co-production method of heat and electricity (CHP, co-production of heat and power) is implemented in the local power plant. This method uses the waste energy from electricity production for district heat and industrial heat/steam. The fuel basis in a CHP plant can include heterogeneous waste fuels. The method has been applied, to a large extent, in only three countries in the world; Denmark, The Netherlands and Finland. Examples of CHP-based industrial ecosystems from Finland are considered. CHP is reflected upon from the viewpoint of industrial ecosystem principles.     

Energy and environmental attitudes in the green state of Denmark: Implications for energy democracy,low carbon transitions,and energy literacy

This article investigates how a mix of energy-users from Denmark perceives energy and environmental issues such as the affordability of electricity and gasoline, the seriousness of climate change, and preferences for different energy systems. Its primary source of data is a pilot survey and energy literacy test distributed in English and Danish to 328 respondents spread across the country. The survey results are used to test four propositions about energy prices, being “green,” public knowledge and competence about energy issues, and self-sufficiency and sustainable technology. The data supports the propositions that Danes identify with “being green” and prefer national and local policies that endorse sustainable technology and being self-sufficient. However, the data also challenges the propositions that Danes would prioritize low energy prices and affordability as key energy concerns and that they are knowledgeable about energy and environmental issues. In this way, a problematic gap may exist between what many academic articles (and previous surveys) report Danish attitudes to be and what this study suggests they are. Given Denmark's ambitious low-carbon goals, these findings have clear relevance to other communities and countries seeking to decarbonize their own energy sectors.     

用于库房温湿度控制的太阳能发电系统研究

设计了采用离网光伏发电和大容量蓄电池储能为基本供电模式的智能库房温湿度监控系统,以太阳能发电系统关键技术为研究重点,分析建立了与气候条件和库房管理要求相关联的发电系统负载计算、发电系统容量计算的数学理论方法,阐述了太阳能电池板优化原理,为太阳能发电技术在库房温湿度环境控制上的应用提供了模式和方法。     

“双碳”背景下河南省电力行业中长期控煤降碳路径

电力行业实现二氧化碳排放尽早达峰并加快脱碳进度,对河南省实现碳达峰碳中和目标具有重要意义.基于碳排放-能源集成模型（iCEM）,对河南电力行业“双碳”目标下控煤降碳路径开展情景研究.结果表明,综合考虑电源结构优化和技术进步等措施,河南省电力行业碳排放将于2028~2033年实现碳达峰,电力行业煤炭消费量在“十四五”期间仍呈持续增长趋势,达峰区间为2027~2031年.大力发展以风电和太阳能为主的清洁能源,采用更多低碳零碳热源、提高外调电比例、加大煤电节能改造是碳达峰目标约束下河南省控煤主要措施.碳中和阶段,布局内陆核电是缓解河南省控煤压力与实现“双碳”目标的重要路径之一,需要提前开展论证研究.加速推进落后机组淘汰和现役机组节能改造、加速发展非化石能源发电、超前规划外调电,并配套完善煤电退出和调峰的市场机制、增加系统灵活性、加快外引清洁能源保障等政策,是河南省电力行业控煤降碳路径有效的政策保障.     

Integration of Solid Oxide Fuel Cell in a sugar-ethanol factory: analysis of the efficiency and the environmental profile of the products

The effect of the integration of Solid Oxide Fuel Cell (SOFC) technology in a sugar-ethanol factory on the environmental profile/footprint of the products (sugar, ethanol, electricity) is evaluated. The sugarcane is the primary feedstock and sugar, ethanol and electricity are the main products of the system, where the functional unit is defined as 9.86 ton/h of sugar, 2.195 ton/h of hydrated ethanol (96% w/w) and 847 kWh of electricity. A detailed set of material and energy inputs and outputs was obtained from a local factory and was completed using simulation data by Aspen Plus^®.The environmental impacts (greenhouse gases and air pollution), exergy efficiency and a renewability parameter have been considered as indicators for the comparative assessment with conventional sugar, ethanol and electricity production technologies. The results show that the use of a SOFC technology involves a reduction of greenhouse gas emissions (52-55%) and non-renewable resources (60-64%) when compared with the conventional integrated sugar and ethanol plant. The higher renewability index (0.93) and exergy efficiency (38%) are noticed for the Solid Oxide Fuel Cell technology integrated in the sugar-ethanol factory than conventional sugar-ethanol plant.     

Assessing the uptake of small-scale photovoltaic electricity production in Argentina: the PERMER project

Supplying electricity to remote rural communities in lesser developed countries (LDCs) is key to improving livelihoods and reducing poverty. Decentralised renewable energy systems such as solar photovoltaic (PV) electricity have the potential to provide a viable and sustainable alternative to overcome the physical and economic barriers facing the expansion of low and medium tension grids. This paper critically assesses the impact of small-scale PV systems installed in homes, schools and public buildings over the last six years under the PERMER project—Renewable Energy Project for the Rural Electricity Market—co-funded by a range of public and private sources. The structure of financial subsidies has enabled these remote rural communities to receive an electricity supply that, in many cases, would otherwise not have been possible. Replacing traditional energy sources such as candles and kerosene lamps, the PV electricity systems are providing better quality light, reducing indoor air pollution levels, as well as a means to power communications technologies and extend hours for cultural and productive activities. There are, however, certain technical, organisational and intellectual barriers that remain to be overcome before the project can be considered to be operating optimally.     

Cost efficiency analysis and emission reduction by implementation of energy efficiency standards for electric motors

The industrial sector is the biggest electricity consumer in Malaysia. Electric motors account for more than 45% of the electricity consumption in the industrial sector in the country. Therefore, it is very important to implement energy efficiency standards for electric motors to reduce energy consumption growth in this sector. This paper attempts to calculate the cost efficiency analysis and emission reduction by implementing energy efficiency standards for electric motor in Malaysia. The energy efficiency standards are proposed based on the efficiency of electric motors from survey data. The study examines the potential energy, economical and environmental impacts of the implementation of energy efficiency standards for electric motors in three scenarios i.e. 0.5%, 1.0% and 1.5% of standards efficiency improvement. Standards also enable consumers to reduce their electricity bill and contribute to a positive environmental impact.