Energy conservation and circular economy in China's process industries

Since energy consumption in process industries accounts for a great proportion of China's total energy consumption, energy conservation becomes the practical choice to reduce the conflict between energy demand and energy supply in China, and therefore, promoting energy conservation is the long-term solution to China's energy and environment problems from the source. In this paper, based on the introduction of the concept of energy consumption status in China's key energy-consuming process industries, the main technical bottlenecks and resource-environment problems were analyzed with special emphasis on energy utilization efficiency, energy consumption mode, and waste emission. As for the measures to resolve these problems, at the policy level, policies and programs of Chinese government related to energy conservation were introduced in combination with China's circular economy structure. At the technical level, the key technologies and research progress to improve energy utilization efficiency, reducing energy consumption, as well as utilizing the resource of discharged wastes were reviewed. Finally, three typical cases of the development of circular economy at three levels, namely the chemical industry, metallurgical industry, and electric power industry, were studied for the enforcement of circular economy and energy conservation in China's process industries.     

The achievement,significance and future prospect of China's renewable energy initiative

China's high-speed economic growth and ambitious urbanization depend heavily on the massive consumption of fossil fuel. However, the over-dependence on the depleting fossil fuels causes severe environmental problems, making China the largest energy consumer and the biggest CO₂ emitter in the world. Faced with significant challenges in terms of managing its environment and moving forward with the concept of sustainable economic development, the Chinese government plans to move away from fossil fuels and rely on renewables such as hydropower, wind power, solar power, biomass power and nuclear power. In this paper, the current status of China's renewable energy deployment and the ongoing development projects are summarized and discussed. Most recent developments of major renewable energy sources are clearly reviewed. Additionally, the renewable energy development policies including laws and regulations, economic encouragement, technical research and development are also summarized. This study showcases China's achievements in exploiting its abundant domestic renewable energy sources to meet the future energy demand and reducing carbon emissions. To move toward a low carbon society, technological progress and policy improvements are needed for improving grid access (wind), securing nuclear fuel supplies and managing safety protocols (nuclear), integrating supply chains to achieve indigenous manufacture of technologies across supply chains (solar). Beyond that, a preliminary prediction of the development of China's future renewable energy developments, and proposes targeted countermeasures and suggestions are proposed. The proposal involves developing smart-grid system, investing on renewable energy research, improving the feed-in tariff system and clarifying the subsidy system.     

Status quo of China hydrogen strategy in the field of transportation and international comparisons

This paper discusses the current development strategy, technology and industrialization of China's hydrogen energy industry in the transportation field, summarizes the characteristics and development experience, and makes a comparative study with the situation of some developed countries. The results show that the current development of hydrogen energy has formed a broad consensus in China and is becoming the overall development of China's national level consciousness. However, China's hydrogen energy industry is still facing problems such as high cost of comprehensive utilization, imperfect standards and regulations for hydrogen energy utilization, obvious tendency of industrial blind development and structural overcapacity risk. Therefore, some policy suggestions were proposed for the future development, such as strengthening top-level design, strengthening pilot demonstration, promoting the development of the whole hydrogen industry chain, and reducing the cost of hydrogen and fuel cell vehicles in the field of transportation.     

Development of solar thermal technologies in China

Solar energy is receiving much more attention in building energy systems in recent years. Solar thermal utilization should be based on integration of solar collectors into buildings. The facades of buildings can be important solar collectors, and, therefore, become multifunctional. In addition, solar collectors can be used to enhance the appearance of the facade when considering their aesthetic compatibility. Currently, installation of collectors on the south tilted roofs, south walls, balconies or awnings of buildings are the feasible approaches for integration of solar collectors into buildings. The most well known solar energy demonstration projects in China are introduced in this paper, which cover different integrated approaches, and solar heating and cooling systems. In China's cities, the process of rebuilding apartment roofs from flat to inclined offers the ideal opportunity to carry out solar renovation in combination with roof-integrated collectors. It can be seen from the demonstration projects over the last twenty years, that, solar cooling systems were mainly used in public buildings for either absorption or adsorption. Besides, nearly all solar cooling systems are multifunctional. They have been used to supply heating and hot water in other seasons for the purpose of high solar fraction. In the 11th Five-year research project (duration 2006–2010), the government has encouraged solar energy researchers to study, develop, and break through the key technologies involved in the integration of solar thermal technologies with buildings.     

Limits to leapfrogging in energy technologies? Evidence from the Chinese automobile industry

Limits to leapfrogging in energy technologies? One of the most attractive notions in the field of sustainable energy development is the concept of energy-technology “leapfrogging”. Leapfrogging through international technology transfer can be especially problematic because often developing countries do not have the technological capabilities to produce or integrate the advanced energy technologies themselves. Until they have acquired the capabilities to produce the advanced technologies themselves, most late-industrializing countries buy their new technologies from industrialized countries, usually through licensing or joint-venture arrangements. Empirical case studies of the three main Sino-US passenger-car joint ventures reveal that until the late 1990s, little energy or environmental leapfrogging occurred in the Chinese automobile industry as the result of the introduction of US automotive technology. An improvement in Chinese capabilities and more stringent Chinese energy and environmental policies are needed to induce energy leapfrogging in the Chinese automobile industry. Foreign firms also have a social responsibility to contribute to China's sustainable industrial development. In order to realize the promise of the leapfrogging, the limits to leapfrogging must be identified and acknowledged so that strategies can be devised to surmount the barriers to the introduction of advanced energy technologies in developing countries.     

Clean coal technology development in China

Coal is found in huge amounts throughout the world and is expected to play a crucial role as an abundant energy source. However, one critical issue in promoting coal utilization is controlling environmental pollution. Clean coal technologies are needed to utilize coal in an environmentally acceptable way and to improve coal utilization efficiency. This paper describes coal's role in China's energy system and the environmental issues related to coal use. Coal is responsible for 90% of the SO₂ emissions, 70% of the dust emissions, 67% of the NO_x emissions, and 70% of the CO₂ emissions. But as the most abundant energy resource, it will continue to be the dominant energy supply for a long time. Therefore, the development and deployment of clean coal technologies are crucial to promote sustainable development in China. Clean coal technologies currently being developed in China are described including high efficiency combustion and advanced power generation technologies, coal transformation technologies, IGCC (integrated gasification combined cycle) and carbon capture and storage (CCS). Although China only recently began developing clean coal technologies, there have been many successes. Most recent orders of coal-fired power plants are units larger than 600 MW and new orders for supercritical and ultra supercritical systems are increasing rapidly. Many national research programs, industrial research programs and international collaboration projects have been launched to develop on IGCC and CCS systems in China. Finally, suggestions are given on how to further promote clean coal technologies in China.     

Re-thinking china's densified biomass fuel policies: Large or small scale?

Current policies and strategies related to the utilization of densified biomass fuel (DBF) in China are mainly focused on medium- or large-scale manufacturing modes, which cannot provide feasible solutions to solve the household energy problems in China's rural areas. To simplify commercial processes related to the collection of DBF feedstock and the production and utilization of fuel, a novel village-scale DBF approach is proposed. Pilot demonstration projects have shown the feasibility and flexibility of this new approach in realizing sustainable development in rural China. Effective utilization of DBF in rural China will lead to gains for global, regional, and local energy savings, environmental protection, sustainable development, and related social benefits. It could also benefit other developing countries for better utilization of biomass as a viable household energy source. This proposal therefore delivers the possibility of reciprocal gains, and as such deserves the attention of policy makers and various stakeholders.     

Green nanotechnology of trends in future energy: a review

It is well known that current fossil fuel usage is unsustainable and associated with greenhouse gas production. The amount of the world's primary energy supply provided by renewable energy technologies is urgently required. Therefore, the relevant technologies such as hydrogen fuel, solar cell, biotechnology based on nanotechnology, and the relevant patents for exploiting the future energy for the friendly environment are reviewed. At the same time, it is pointed out that the significantly feasible world's eco‐energy for the foreseeable future should not only be realized, but also methods for using the current energy and their by‐products more efficiently should be found correspondingly, alongside technologies that will ensure minimal environmental impact. Copyright © 2011 John Wiley & Sons, Ltd.     

生物质能发电技术分析

在不可再生能源濒临枯竭,环境污染日益加剧的今天,生物质能源替代化石能源利用的研究和开发,已成为国内外学者研究和关注的热点。介绍了国内外生物质能的主要转化利用技术,分析了生物质直接燃烧发电技术和气化发电技术,提出了符合能量梯级利用原则的生物质能发电方式,将是生物质能利用的主要形式。     

Strategic thinking on IGCC development in China

With electricity demand growing at a torrid pace—about 15% per year, faster than any other country in the world—China is fast-tracking the construction of new generation facilities, about 80% of which are coal-fired. China's total capacity in the reference scenario of World Energy Outlook 2006 (WEO2006) released by the International Energy Agency (IEA) is projected to practically 3.4 times, from 442 GW in 2004 to 1496 GW in 2030, growing at 4.8% per year on average. The vast majority of this huge generation requirement will still be met through the construction of coal power plants. Because new coal power plants built today have a long life cycle and are not easy to upgrade the technologies involved, decisions made now will have a major impact on the coal utilization mode in the coming years. Thus, the future 20 years is the strategic opportunity period of the transition of conventional coal utilization. Because the Integrated Gasification Combined Cycle (IGCC) can supply electricity, liquid fuels, hydrogen and other chemicals if needed at low pollution level, and has the potential to make carbon capture and sequestration much easier and cheaper than traditional pulverized coal boiler power plants, it should be the strategic direction for China to meet the requirements of the energy and environmental challenges. This paper makes an overview of China's energy and environmental challenges and opportunities, and describes the IGCC technology. It discusses why China should develop IGCC. What are the foundations for China to develop IGCC? What are the rational driving forces to develop IGCC in China? What is the reasonable developing path of IGCC in China?     

Analysis of China's energy utilization for 2007

China is the world's second-largest energy producer and consumer, so that it is very necessary to analyze China's energy situation for saving energy consumption and reducing GHG emission. Energy flow chart is taken as a useful tool for sorting out and displaying energy statistics data. Energy statistics data is the premise and foundation for analyzing energy situation. However, there exit many differences between China and foreign energy balance. Based on the international criterion of energy balance and some advices given by related experts, the author properly adjusts China's energy balance. And the purpose of this paper is to draft China's energy flow chart for 2007, which is used to study the characteristics of energy production and consumption in China. We find that: (1) coal is the main energy in China, which accounted for 73.2% of total energy supply in 2007; (2) thermal power accounted for 83.2% of the total electricity supply, and 78.43% thermal power was based on coal; (3) in 2007, the secondary industrial sector consumed about 69.93% of energy; (4) China's energy utilization efficiency was about 33.23% in 2007.     

Integration of thermal energy and seawater desalination

Energy and freshwater shortage are the bottlenecks restricting China's economic development. The integration of energy utilization system and seawater desalination is considered as an innovative technology enabling efficient simultaneous use of middle or low temperature thermal energy and supply freshwater. Three feasible approaches to integrate seawater desalination with energy utilization system are presented in this paper, including combinations of the desalination process with a Combined Cooling Heating & Power system (CCHP), a power plant, or a solar thermal utilization system. In addition, the feasibility and advantages of a seawater desalination system combined with a power plant are described. The findings indicate that combining seawater desalination with industrial processes is a feasible and promising way to solve the problems of the lack of freshwater and low efficient use of low temperature thermal energy in coastland areas.     

Green energy strategies for sustainable development

In this study we propose some green energy strategies for sustainable development. In this regard, seven green energy strategies are taken into consideration to determine the sectoral, technological, and application impact ratios. Based on these ratios, we derive a new parameter as the green energy impact ratio. In addition, the green energy-based sustainability ratio is obtained by depending upon the green energy impact ratio, and the green energy utilization ratio that is calculated using actual energy data taken from literature. In order to verify these parameters, three cases are considered. Consequently, it can be considered that the sectoral impact ratio is more important and should be kept constant as much as possible in a green energy policy implementation. Moreover, the green energy-based sustainability ratio increases with an increase of technological, sectoral, and application impact ratios. This means that all negative effects on the industrial, technological, sectoral and social developments partially and/or completely decrease throughout the transition and utilization to and of green energy and technologies when possible sustainable energy strategies are preferred and applied. Thus, the sustainable energy strategies can make an important contribution to the economies of the countries where green energy (e.g., wind, solar, tidal, biomass) is abundantly produced. Therefore, the investment in green energy supply and progress should be encouraged by governments and other authorities for a green energy replacement of fossil fuels for more environmentally benign and sustainable future.     

我国可再生能源发展对策

可再生能源的开发利用是应对气候变化和满足能源需求持续增长的最现实的举措。2009年我国风电和太阳能光伏发电保持了快速发展势头,其中风电装机容量估计达到约2200×104kW,但非化石能源消费量在能源消费总量中所占的比重仍然很低。2009年,我国能源消费总量约为31×108t标煤,其中水电、核电、风电等商品化非化石能源消费量约为2.3×108t标煤,约占能源消费总量的7.4%。要完成到2020年我国非化石能源在能源消费总量中所占比例达到15%的目标,任务非常艰巨。加快开发利用可再生能源是能源发展的重要任务之一,到2020年,可再生能源开发利用总量将在2008年的基础上增加2倍以上。我国目前和今后10多年时间内,可再生能源发展的重点是水电、风电、太阳能和生物质能。加快发展我国可再生能源的举措有:①继续做好水电建设工作,促进水电持续健康发展;②有序推进风电的规模化发展,显著提高风电在电力结构中的比重;③加快推广太阳能利用技术,扩大太阳能开发利用规模;④因地制宜开发利用生物质能,提高生物质能利用的现代技术水平。     

Residual coal exploitation and its impact on sustainable development of the coal industry in China

Although China owns large coal reserves, it now faces the problem of depletion of its coal resources in advance. The coal-based energy mix in China will not change in the short term, and a means of delaying the coal resources depletion is therefore urgently required. The residual coal was exploited first with a lower recovery percentage and was evaluated as commercially valuable damaged coal. This approach is in comparison to past evaluations when the residual coal was allocated as exploitation losses. Coal recovery rates, the calculation method of residual coal reserves and statistics of its mines in China were given. On this basis, a discussion concerning the impacts on the delay of China's coal depletion, development of coal exploitation and sustainable developments, as well as technologies and relevant policies, were presented. It is considered that the exploitation of residual coal can effectively delay China's coal depletion, inhibit the construction of new mines, redress the imbalance between supply and demand of coal in eastern China, improve the mining area environment and guarantee social stability. The Chinese government supports the exploitation technologies of residual coal. Hence, exploiting residual coal is of considerable importance in sustainable development of the coal industry in China.     

Renewable energy in the South Pacific—options and constraints

Over the last fifteen years the small island nations in the South Pacific have seen the introduction of various forms of renewable energy technologies. In spite of high expectations from the development of indigenous renewable energy resources using nonconventional approaches (wind power, wave power, ocean thermal energy conversion, biogas digestors, biomass gasifiers), these technologies have largely failed to develop into viable alternatives to conventional approaches (based on imported petroleum, biomass and hydroelectric power). Among the few exceptions are solar photovoltaic power for remote islands, especially when provided through a utility type institution, solar water heaters, and the use of biomass wastes by agroindustries. As a result, all the island countries are still heavily dependent on fossil fuels for their energy requirements. Some of them to such an extent that their petroleum imports are up to 500% of their total exports.As far as acceptance of new renewable energy technologies by the Pacific communities goes hasty decisions and introductions have done more harm than good.     

Competitiveness assessment of the biomass power generation industry in China: A five forces model study

China is facing a number of energy related challenges including a shortage of electricity supply, depletion of fossil fuels and environmental pollution. These challenges make it important to develop renewable energy resources. As per other renewable energy industries, the biomass power industry is facing a series of opportunities and challenges. Utilizing Michael Porter's Five Forces Model theory for analyzing the competitive environment and the competitive situation of an industry, this paper establishes a Five Forces Model for assessing the competitiveness of China's biomass power industry. Inputs for this model include semi-structured interviews with biomass power generation enterprises and a critical analysis of the national policy framework along with relevant literature and official statistics. Five major stakeholders of China's biomass power industry, namely competitors, suppliers, buyers, potential competitors, and substitutes are assessed to determine their influence on the biomass power generation industry. This assessment highlighted the current status, existing issues and future prospects of the biomass power industry. Similarly, it provides assistance to develop procurement strategies for the sustainable development of the industry.     

盐城新能源产业现状及发展趋势研究

目前盐城市新能源主要有风能、太阳能、生物质能以及新能源汽车产业。其中,盐城新能源汽车产业正处于起步发展的关键阶段;风能、太阳能和生物质能的开发利用正处于加速发展的起步阶段,尤其是风电装备产业发展迅速。盐城发展新能源产业具有机遇良好、自然资源优越、产业基础雄厚等优势。但同时也存在风电装备产业发展仍相对滞后、风电场土地使用不够集约、太阳能光伏产业发展陷入低潮、新能源汽车推广普及还有难度,缺乏整体规划、研发能力薄弱等制约因素;另外还存在技术障碍、运营成本高、安全与环境问题、盈利困难等产业繁荣背后的隐忧。应努力做好规划和组织引导工作,建立研发投入机制;继续加大扶持力度,改善政策环境和市场条件;注重整机的引进和大企业拉动;加大科技投入,增强研发能力;继续推进新能源汽车产业建设,以求做大做强。     

Analysis of the market penetration of clean coal technologies and its impacts in China's electricity sector

This paper discusses policy instruments for promoting the market penetration of clean coal technologies (CCTs) into China's electricity sector and the evaluation of corresponding effects. Based on the reality that coal will remain the predominant fuel to generate electricity and conventional pulverized coal boiler power plants have serious impacts on environment degradation, development of clean coal technologies could be one alternative to meet China's fast growing demand of electricity as well as protect the already fragile environment. A multi-period market equilibrium model is applied and an electricity model of China is established to forecast changes in the electricity system up to 2030s. Three policy instruments: SO₂ emission charge, CO₂ emission charge and implementing subsidies are considered in this research. The results show that all instruments cause a significant shift in China's electricity structure, promote CCTs’ competitiveness and lead China to gain great benefit in both resource saving and environment improvement. Since resource security and environment degradation are becoming primary concerns in China, policies that could help to gain generations’ market share of advanced coal-based technologies such as CCTs’ is suitable for the current situation of China's electricity sector.