绿色新能源汽车发展外文文献翻译2017

文献出处：Moriarty P, Honnery D. The prospects for global green car mobility[J]. Journal of Cleaner Production, 2008, 16(16): 1717-1726.原文The prospects for global green car mobilityPatrick Moriarty, Damon HonneryAbstractThe quest for green car mobility faces two major challenges: air pollution from exhaust emissions and global climate change from greenhouse gas emissions. Vehicle air pollution emissions are being successfully tackled in many countries by technical solutions such as low-sulphur fuels, unleaded petrol and three-way catalytic converters. Many researchers advocate a similar approach for overcoming transport's climate change impacts. This study argues that finding a technical solution for this problem is not possible. Instead, the world will have to move to an alternative surface transport system involving far lower levels of motorised travel.Keywords：Green mobility; Fuel efficiency; Alternative fuels; Global climate change; air pollution1. IntroductionProvision of environmentally sustainable (or green) private transport throughout the world faces two main challenges. The first is urban and even regional air pollution, particularly in the rapidly growing cities of the industrialising world. The second is global climate change, caused mainly by rising concentrations of greenhouse gases (GHGs) in the atmosphere. These two barriers to green car mobility differ in several important ways. First, road traffic air pollution problems are more localised, because of the short atmospheric lifetimes of most vehicle pollutants and . Thus regional solutions are often not only possible, but also essential – Australian cities, for example, can (and must) solve their air pollution problems themselves. Matters are very different for global climate change. Except possibly for geo-engineering measuressuch as placing large quantities of sulphate aerosols in the lower stratosphere or erecting huge reflecting mirrors in space, one country cannot solve this problem alone. Climate change is a global problem. Nevertheless, it is possible for some countries to ‘freeload’ if the majority of nations that are important GHG emitter。

绿色出行新能源汽车的好处英语作文New Energy Vehicles: The Future of Green TransportationHello, my name is Emily, and I'm a 10-year-old girl who loves learning about science and technology. Today, I want to talk to you about something that I find really exciting – new energy vehicles! These cars are also called electric vehicles or EVs, and they are becoming more and more popular all over the world.Why are new energy vehicles so great? Well, there are a lot of reasons, but the biggest one is that they are much better for the environment than regular gas-powered cars. You see, when we burn gasoline or diesel in regular cars, it releases a lot of harmful gases into the air, like carbon dioxide and nitrogen oxides. These gases are called greenhouse gases, and they are one of the main causes of climate change.Climate change is a really big problem that affects the whole planet. It's making the Earth warmer, which is causing things like melting glaciers, rising sea levels, and more extreme weather events like hurricanes and droughts. It's also hurting a lot of animals and plants by changing their habitats.But new energy vehicles don't burn any gasoline or diesel at all! Instead, they run on electricity stored in big batteries. Andthe electricity to charge these batteries can come from clean energy sources like solar power, wind power, or hydroelectric power. That means that new energy vehicles don't produce any direct emissions while they're being driven, which is much better for the environment and helps reduce climate change.Another great thing about new energy vehicles is that they are much quieter than regular cars. This is because they don't have a loud, rumbling gasoline engine. Instead, they have an electric motor that makes very little noise. This can make cities and neighborhoods much quieter and more peaceful places to live.New energy vehicles are also a lot cheaper to operate than regular cars in the long run. While they might cost a bit more to buy at first, you don't have to spend money on gasoline or diesel fuel to run them. Instead, you just need to pay for the electricity to charge the batteries, which is usually much cheaper than buying gas. And since new energy vehicles have fewer moving parts than regular cars, they also require less maintenance and repairs over time, which can save you even more money.But don't worry, scientists and engineers are working hard to make batteries with even longer ranges, and more and morecharging stations are being built all over the world to make it easier to recharge your vehicle when you're on the go.Another challenge with new energy vehicles is that they can still be a bit more expensive to buy than regular cars, especially if you want one with a really long range. But the good news is that the prices are coming down all the time as the technology improves and more people start buying them.Overall, I think new energy vehicles are really cool and exciting, and I can't wait to see how they keep getting better and better in the future. They're not only great for the environment and helping to fight climate change, but they're also cheaper to run, quieter, and can save you money in the long run.I hope that when I grow up, most people will be driving new energy vehicles instead of regular gas-powered cars. And who knows, maybe by then we'll have even cooler technologies like flying cars or cars that can drive themselves! But for now, I'm just really happy that we have new energy vehicles to help us take care of our planet and create a cleaner, greener future for everyone.。

关于新能源汽车发展的英语作文The Evolution and Prospects of New Energy Vehicles.The automotive industry has undergone significant transformations over the decades, with the emergence of new energy vehicles (NEVs) marking a paradigm shift in sustainable transportation. These vehicles, powered by sources like electricity, hydrogen fuel cells, or alternative fuels, aim to reduce environmental impacts while offering efficient and cost-effective mobility solutions.Background and Evolution.The concept of NEVs dates back to the early 19th century, with the invention of the first electric car by Thomas Davenport. However, it was not until recent years that the technology matured and became commercially viable. This evolution can be attributed to advancements in battery technology, charging infrastructure, and governmentpolicies promoting sustainable transportation.Electric vehicles (EVs) are the most common type of NEVs, using lithium-ion batteries to power their motors. These batteries offer higher energy density and longer lifespans, enabling EVs to travel longer distances on a single charge. Hydrogen fuel cell vehicles (FCEVs) are another promising technology, converting hydrogen into electricity and water, emitting only water vapor as a by-product.Current Status and Applications.Currently, NEVs are being used in various applications, from personal transportation to commercial fleets andpublic transportation systems. Governments worldwide are providing incentives like tax credits, subsidies, and exemptions from certain road taxes to encourage the adoption of these vehicles.In the passenger car segment, EVs have gainedpopularity due to their reduced fuel costs, lowermaintenance requirements, and environmental benefits. Manufacturers like Tesla, Nissan, and BMW have introduced a range of EV models, catering to different consumer segments.In the commercial sector, NEVs are being used for logistics and delivery, taxi services, and public transportation. Electric buses and taxis are becoming increasingly common in cities worldwide, reducing carbon emissions and noise pollution.Challenges and Solutions.Despite the progress made, several challenges remain in the widespread adoption of NEVs. Range anxiety, or the fear of not being able to reach a charging station before the battery runs out, is a significant concern for manypotential buyers. To address this, manufacturers are developing batteries with higher energy densities andfaster charging speeds.Infrastructure development is another key challenge. Charging stations and hydrogen fueling stations are stilllimited in many regions, making it difficult for NEVs to compete with traditional vehicles. Governments and private companies are investing in building out these networks to ensure widespread accessibility.The cost of NEVs is also a barrier for some consumers. While the upfront cost may be higher than traditional vehicles, the long-term savings in fuel and maintenance costs can offset this. Manufacturers are also working to reduce production costs and make NEVs more affordable.Future Prospects.The future of NEVs looks bright, with continued advancements in technology and infrastructure expected to drive their adoption. Autonomous vehicles, which can optimize energy usage and routing, could further enhancethe efficiency of NEVs.In terms of policy, governments are likely to continue promoting sustainable transportation by providingincentives for NEV ownership and infrastructure development.This, coupled with the decreasing cost of batteries and other components, could lead to a significant increase in NEV sales in the coming years.Conclusion.The development of new energy vehicles represents a significant step towards sustainable transportation. While challenges remain, the industry is making progress in addressing them, and the future looks promising. With continued innovation and support from governments and private sector, NEVs could become the norm in transportation, leading to a more environmentally friendly and efficient future.。

发展电动汽车英文作文英文回答：The development of electric vehicles (EVs) is essential for a sustainable future. EVs offer numerous environmental and economic benefits over conventional gasoline-powered vehicles.Environmental Benefits:Reduced greenhouse gas emissions: EVs do not emit tailpipe emissions, which are a major contributor to climate change.Improved air quality: EVs eliminate pollutants such as carbon monoxide, nitrogen oxides, and particulate matter, improving air quality and reducing respiratory problems.Conservation of fossil fuels: EVs reduce our reliance on finite fossil fuels, which are a major source ofenvironmental pollution and geopolitical instability.Economic Benefits:Lower operating costs: Electricity is significantly cheaper than gasoline, resulting in substantial fuel savings for EV owners.Reduced maintenance costs: EVs have fewer moving parts than gasoline-powered vehicles, which reduces maintenance costs and downtime.Tax incentives and government support: Many governments offer tax credits and other incentives to encourage EV adoption.Technological Advancements:Improved battery technology: Advances in battery technology have increased the range and efficiency of EVs, making them more practical for daily use.Fast charging infrastructure: The expansion of fast charging stations allows EVs to be recharged quickly and conveniently.Connected vehicles: EVs are equipped with sophisticated sensors and software that enable advanced features such as remote diagnostics, navigation assistance, and even self-driving capabilities.Challenges and Opportunities:Charging infrastructure: The availability of reliable and accessible charging infrastructure is crucial for widespread EV adoption.Range anxiety: Concerns about running out of charge remain a barrier for some potential EV buyers.Battery life and replacement costs: EV batteries have a limited lifespan and must eventually be replaced, which can be expensive.Conclusion:The development of electric vehicles is driven by a compelling combination of environmental, economic, and technological benefits. By addressing the challenges and seizing the opportunities, we can accelerate the transition to a cleaner and more sustainable transportation future.中文回答：电动汽车的发展。

外文文献翻译原文及译文文献出处：Pack Damon . The research of green new energy velucles fJ]. Journal of Cleaner Production，2017, 1(6): 17-26.原文The research of sreen new energy vehiclesPack Damon1. IntroductionProvision of environmentally sustainable (or green) private transport throughout the world faces two main challenges. The first is urban and even regional air pollution, particularly in the rapidly growing cities of the industrializing world. The second is global climate change, caused mainly by rising concentrations of greenhouse gases (GHGs) in the atmosphere. These two barriers to green car mobility differ in several important ways. First, road traffic air pollution problems are more localized, because o f the short atmospheric lifetimes of most vehicle pollutants and • Thus regional solutions are often not only possible, but also essential - Australian cities, for example, can (and must) solve their air pollution problems themselves- Matters are very different for global climate change. Except possibly for geo-engineering measures such as placing large quantities of sulphate aerosols in the lower stratosphere or erecting huge reflecting mirrors in space，one country cannot solve this problem alone.Climate change is a global problem. Nevertheless, it is possible for some countries to ‘freeload’ if the majority of nations that are important GHG emitter.Second，there is agreement that air pollution, especially in urban areas，is potentially a serious health hazard，and that road transport can contribute greatly to urban pollutant level • For these reasons, governments in many countries are already taking effective action on air pollution. But until recently, climate change was not recognized as a major problem by some key policy makers, and all countries have yet to take effective action on reducing emissions.Third, vehicular air pollutant problems，at least in the Organisation for Economic Cooperation and Development (OECD) countries, are already showing themselves amenable to various technical solutions, such as low-sulphur fuels, unleaded petrol, and three-way catalytic converters. Some researchers have argued explicitly that global transport emissions can be reduced to very low levels with a combination of two key technical solutions - large improvements in vehicle fuel efficiency and a switch to alternative transport fuels, such as liquia biofuels and hydrogen derived from renewable energy. A much larger group implicitly support this position by projecting large future increases in car numbers and travel and even a globally interconnected highway system.Further，governments throughout the world have endorsed the United Nations Framework Convention on Climate Change (which cameinto effect in 1994), but at the same time are expanding their road networks，encouraging their car industry，and planning for future car traffic expansion. Overall, the majority of both researchers and policy makers appear to consider that climate change poses no threat to global car mobility. Nevertheless, other researchers argue in general that technology cannot solve the serious environment/resource problems the world faces global warming in particular. Also，the authors themselves have earlier questioned whether the current global transport system can continue on its present course. This paper attempts to resolve these competing claims.Transport, of course, is not the only source of either air pollution or global climate change. All energy-using sectors, and even land-use changes，can contribute to these two problems. It is thus important that any attempts to reduce transport^ emissions do not compromise similar efforts in other sectors of the economy. It is also possible that emission reduction policies in one country could adversely affect reduction efforts elsewhere.The aim of this paper is to show that private car travel cannot form the basis for a sustainable global system of surface passenger travel. To simplify the analysis, only GHG emissions will be analysed. We argue that the risk of global climate change requires effective reductions in the next two decades or so, whereas technical solutions to drastically cut car traveFs greenhouse gas emissions are only possible in a much longer time frame, and, in some cases，possibly not even then. Overall, the world willhave to rely on alternative modes (various forms of public transport，walking and cycling), and，for much of the industrialised world， much-reduced levels of personal travel as well. Of course, it is quite possible that the limited time frame available is also much too short for travel reductions and modal shifts of the magnitude proposed here. The conclusions of this paper have relevance for freight and air transport, and also for other sectors of the economy faced with the need for deep cuts in GHG emissions.2. Global climate change and global car travelThe vast majority of climate scientists support the view that emissions of heat-trapping gases into the atmosphere, particularly C02, from fossil fuel combustion and land-use changes, cause global warming by altering the earth's radiation balance. The 2007 report from the Intergovernmental Panel on Climate Change (IPCC) states that sea levels are rising，glaciers and sea ice cover are diminishing，and 11 of the 12 warmest years since 1850 have occurred in the 1995-2006 period. Their latest estimate (with a probability of 66% or greater) for climate sensitivity - the equilibrium increase in global temperature resulting from a doubling of C02 in the atmosphere - is from 2.0 °C to 4.5 °C, with a best estimate of 3-0 °C . Atmospheric C02 concentrations are currently rising by some two parts per million (ppm) annually.Moreover, large positive feedback effects could result in emissions, and thus temperatures，rising much more rapidly than expectedon the basis of present fuel and land-use emission releases. One such feedback is large-scale methane release from northern tundra as permafrost melts. There is some preliminary evidence that this process is already underway and. Further，studies of past climate have shown that abrupt climatic change can occur over the course of a decade or even a few years and • James Hansen，a prominent US climate scientist，has argued on the basis of paleoclimatic data that if further global warming is not limited to 1 °C beyond the year 2000 value，feedbacks could add to business-as-usual emissions，making the world a ‘different planet’. His 1 °C rise above the year 2000 figure is only slightly below the EU value of 2 °C above the pre-industrial value, given the estimated 0.74 °C warming that has occurred since 1880. He concludes that we can only continue present trends for GHG emissions for another decade or so before committing the climate to irreversible change. Here, we take a position intermediate between den Elzen and Meinshausen and Hansen, and assume that by 2030 global emissions of both C02 and other GHGs must be reduced to 25% their current value - a four-fold reduction in current global emissions.Thus, to limit dangerous climatic change, annual emissions to the atmosphere of C02 and other greenhouse gases will need to be greatly curtailed, unless geo-engineering or carbon sequestration techniques can be successfully deployed in time. Equal emissions per capita for all countries，as advocated by ‘contraction and convergence’ proponents，are likely to bethe only acceptable proposal, since it is improbable that industrialising countries such as China or India will permanently accept lower per capita emissions than the already industrialised countries. They could go further，and demand parity in cumulative per capita emissions over the past century for C02, a long-lived gas. Such an approach would require the already industrialised countries to reduce emissions to near zero. In 2003，global C02 emissions from fossil fuels averaged 4.2 t/capita, but varied widely from country to country. The US, Australian and Japanese emissions were, respectively, 4.8, 43 and 2.2 times larger than the world average, implying reduction factors of roughly 19, 17 and 9. (The US reduction value of 19 by 2030 can be compared with Hussmann’s calculated value of 66，although his reduction is for 2050.) Although many tropical African countries emitted less than 5% of the average global value，most of the industrializing world would also need to reduce emissions. In the absence of reliable national data, we assume here that other GHG emissions for each country follow the same pattern as fossil fuel C02 emissions.What are the implications for transport, and private car travel in particular, of these proposed reductions in GHG emissions? iransport contributed an estimated 19% of global GHG emissions in 1971, but 25% in 2006• In 2003，there were roughly 715 million cars in the world (including light commercial vehicles in the US)，and 6270 million people, for an average car ownership of 114/1000 persons and. But when considered at thenational level，ownership is far from normally distributed Although the global average is 114/1000 persons，only about 18-5% of the world population lived in countries with between 20 and 200 cars/1000 persons. A further 65% lived in countries with less than 20 cars/1000 (including China and India), and the remaining 16.5% in countries with greater - usually far greater - than 200 cars/1000.Clearly, car ownership is presently heavily polarised; people either live in highly motorised countries - usually in the OECD - or in countries with very low levels of car ownership. But the picture is changing. People in all countries，but particularly those in Asia，want to own a car; indeed, Asia reportedly leads the world in aspirations for car ownership . Where incomes are rising rapidly, as in populous China and India, so too are car sales and ownership. In 2006, China，with sales of 4.1 million，became th e world’s third largest market for cars, overtaking Germany (3.4 million cars sold). By 2010 it is forecast that China will move into second place ahead of Japan, with only the US ahead. India sold 1.0 million cars in 2006, and annual sales are rising rapidly there as well. Despite urban congestion problems, these countries see vehicle manufacture as an important part of their industrialization programs, and the major world car companies are investing heavily in new Asian production. In brief, these countries and others want to shift their societies from the low to the high motorization group.What if the whole world moved to the high car ownership group?In the OECD countries，car ownership averages over 450 cars/1000 and，and even in with 500 or more cars/1000, is still growing. In the US, light vehicle ownership at 777/1000 residents in 2004, was 15% larger than the licensed driver population. Global car passenger-km (p-km) in any year is a product of the following three factors:For 2030, the UN median projection for world population is 8.20 billion，and for 2050, 9.08 billion. Assume car ownership per 1000 world population reached an average of 300 in 2030 (which would allow most presently non-motorised countries to attain a basic automobility level of 200 cars/1000 persons), and that the present average p-km/car remains unchanged. World cars would then total 2.46 billion. This projected 2030 value for both total cars and global car p-km is 3.44 times the present world total. Unless fuel efficiency and/or the fuels used change, GHG emissions (and oil consumption) would rise similarly. But，as we have argued, total emissions may well have to be reduced four-fold. Assuming that percentage reductions in car travel emissions must match overall reductions, emissions per car p-km would need to fall about 14-fold by 2030 compared with their present value. The exact value would of course vary from country to country: for the US，Australia and Japan，reduction factors would be 23.6, 22.0 and 8.6, respectively, conservatively assuming no further rise in car numbers in these countries and. Reduction factors would also be high for countries with very low car ownership，but in this case the reductions referto aspirations，not actual travel or emissions. The next two sections examine whether such reductions are possible in the requisite time frame. 3.Greening car mobility: more passenger-km per unit of fuel energyFor GHG emission reductions, the aim is to maximise travel for a given level of C02-e emissions. Thus, p-km/kg C02-e is to be maximised for the global car fleet. This ratio in turn can be expanded into the product of the following three factors:This section deals with occupancy rates and fuel efficiency, which together enable personal travel per MJ of fuel to be increased. The following section examines ways of lowering GHG emissions by using alternative fuels，usually with new power systems. In such analyses，it is important to distinguish between，on the one hand, voluntary change, or politically feasible mandated changes under normal conditions, and on the other, changes due to what climatologists in a different context term ‘external forcing’ 一 for example changes brought about by declining global oil production, or by governments being required to meet serious GHG reduction targets.3.1.Improving occupancy ratesImproving vehicle occupancy has an important advantage: in principle it can be implemented very rapidly with the existing vehicle fleet. The potential efficiency gains are also large. For a typical five-seat car,occupancy rates have effective lower and upper limits of 20% (driver only，equivalent to 1 •0 p-km/v-km) and 100% (all seats occupied)， respectively，but actual overall values in the highly motorised OECD countries seem to fall in the 23-^5% range (1.25-1.75 p-km/v-km).3.2.improving fuel efficiencyImproving the energy efnciency of cars is often seen as a means of addressing not only greenhouse gas emissions，but also air pollution and global oil depletion/supply security. Two general approaches are possible. The first is to decrease the road load — the sum of rolling, inertial, and air resistance - a general approach that will be needed by all future vehicles, whether private or public transport. Reducing the mass of the vehicle by using lighter weight materials is the most important means of decreasing the road load. The second is to improve the share of input energy that drives the wheels. Electric drive is today regarded as the best approach for achieving this aim, mainly because it enables regenerative braking and eliminates idling.4.Greening car mobility: lower emissions per unit of fuel energyOne way around the difficulty of raising vehicle efficiency is to move away from petroleum-based fuels to fuels with a lower GHG emissions impact. A variety of alternative fuels systems have been advocated for road transport as a way of cutting GHG emissions. These include various biomass-based fuels for internal combustion-enginedvehicles, and use of renewable energy to produce hydrogen for fuel cell vehicles or electricity for plug-in hybrids and pure battery electric vehicles. LPG and compressed natural gas are also presently used alternatives to petrol and diesel, but are themselves hydrocarbon fuels in limited supply, and their emission reduction benefits over petrol are minor and . Synthetic fuels made from more abundant coal reserves would double the GHG penalty. Accordingly，this section first looks at biomass義based liquid fuels for existing vehicle types，then at various renewable energy options for alternative propulsion system vehicles.At present, the only transport biofuels produced in quantity are ethanol，chiefly in US and Brazil，but also in an increasing number of other countries, including Australia, and biodiesel, produced mainly in the European Union (EU).The large US and Brazilian ethanol programs are based on corn and sugarcane, respectively, the EU f s biodiesel on rapeseed oil. All are food crops，which limit their expansion in a world with unmet food needs, and a still-growing population and • Alr eady, corn prices have risen steeply, as growers can now sell their corn in either the food or fuel markets. Furthermore, at least for grain ethanol，both in the US and in the EU，the fossil fuel energy inputs are, at best，not much below the energy content of the resulting liquid fueLInitial enthusiasm for pure battery electric vehicles faded whenthe difficulty of matching the range of internal combustion vehicles became apparent. The new focus is on rechargeable battery hybrid vehicles (often called plug-in hybrids), building on the sales success of hybrid cars and. Plug-in hybrids would normally run off an electric motor powered from rechargeable batteries, but could also run on petrol or other liquid fuels from their small conventional engines, thus extending their range.Car companies in recent years have also shown much interest in hydrogen fuel cell vehicles. But a number of studies have shown that when mains electricity is the primary energy source for both plug-in hybrid vehicles and hydrogen fuel cell vehicles, plug-in hybrids are far more energy-efficient. Specifically, when a given car model is a plug-in battery hybrid vehicle，running off its battery, its well-to-wheels energy efficiency will be up to four times higher than when powered by a hydrogen fuel cell，with the hydrogen produced by electrolysis of water, and . GHG emissions will follow a similar pattern. Fuel cell vehicles still face many challenges, and infrastructure provision will be expensive. If the hydrogen is produced from natural gas, fuel cell vehicles are slightly more efficient than battery electric vehicles |60]. But the same study projected that in 2020, hybrid gasoline vehicles will be more energy-efficient (in km/MJ) than either battery electric or fuel cell vehicles using NG-derived hydrogen.5.Sustainable and equitable global transportThe preceding sections examined various options for decreasing the GHG emissions per p-km of car travel, and concluded that largereductions could not be expected any time soon. Cutting emissions from freight and air travel are likely to be even more difficult. Not only do both already have far higher loadings than car travel, but also the long service lives of modern aircraft (up to 50 years), limit rapid fleet turnover and -If deep reductions in overall transport GHGs are needed, correspondingly deep reductions in car p-km will be necessary. This section evaluates the travel changes needed, both in high and low car ownership countries.It follows that in most OECD countries, vehicular travel itself will need to be lowered. Fortunately, a surface transport system based on public transport will have much lower overall passenger travel than the one based on private cars, for several reasons:•Private cars, except for some congested inner urban areas, usually allow higher door-to-door speeds than alternative transport modes. Trips that formerly could not be done in a restricted time frame (e.g. work lunch hour) may now be possible, and most trips will have their time costs reduced. Further, in many cases trips cannot be feasibly undertaken at all by alternative modes.•The structure of private motoring costs usually favours high levels of travel，since fixed costs，especially depreciation, registration and insurance，predominate and . Motorists' travel costs per v-km are thus minimised at higher annual levels of vehicle use.•Serving the travel needs of others involves higher levels of passenger travel compared with alternative modes. For example, a parentchauffeuring a child to school involves two person trips from home to school and one-person trip from school to home. In contrast, travelling by bus involves only one vehicular trip (and walking to school none at all).•Car travel，particularly driving，provides psychological benefits to motorists. To a much greater extent than alternative travel modes, car travel is not solely a derived demand, undertaken to gain access to out-of-home activity. ‘Going for a drive’ can be the reason for a trip. Additionally，car travel provides protection from the elements，freedom from timetables，privacy，and the ability to carry heavy luggage or shopping purchases, all of which encourage more trip-making than would an alternative transport system.Travel patterns (and the activity patterns which underlie them) ofpreviously highly mobile societies will have to change to accommodate lower vehicular travel levels. Some of the reductions can be compensated by much higher levels of non-motorised travel - walking and cycling. At present，OECD non-motorised travel typically only amounts to about 1 km daily, but it is probable that its value for exercise and weight reduction will receive more emphasis. And although large-scale changes in urban form cannot happen fast, changes at the micro-level can. More use could be made of local shopping, entertainment, and recreation centres，and of those destinations easily accessible by public transport. Travellers could once more get used to combining previously separate vehicular trips. Particularly in the transition to the new system, these changes will be easierfor inner city residents, and harder for outer suburban or non-urban residents with less provision for alternative modes. Yet given the entrenchment of the car in western countries，it is difficult to anticipate outcomes from policies to reduce car travel. One way of overcoming this problem is to conduct small-scale social experiments in selected localities (such as for speed reductions, car sharing or parking restrictions) to help understand theirimpact. If successful, they could be more confidently introduced on a wider-scale.译文绿色新能源汽车发展研究PackDamon1引言私人汽车交通运输的环境可持续(或绿色)发展，正面临两个主要挑战。

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中国新能源汽车产业发展现状、问题及对策外文文献以下是一篇关于中国新能源汽车产业发展现状、问题及对策的外文文献，供参考：Title: Current Situation, Problems and Countermeasuresof China's New Energy Vehicle Industry DevelopmentAbstract:With the rapid development of the automotive industry, thenew energy vehicle industry has also emerged as a key focusof development in China. This paper analyzes the current situation of China's new energy vehicle industry, includingits market size, production capacity, and technological level. It identifies several key problems that hinder the further development of the industry, such as insufficient charging infrastructure, high production costs, and lack of consumer acceptance. Additionally, the paper proposes a set of countermeasures to address these problems, includingexpanding the charging infrastructure network, increasing government subsidies, promoting technological innovation, and strengthening consumer education and awareness. These countermeasures are aimed at promoting the sustainable and healthy development of China's new energy vehicle industry.Keywords: new energy vehicle industry, current situation, problems, countermeasures1. IntroductionWith the increasing global awareness of environmental protection, new energy vehicles (NEVs) have gainedsignificant attention in recent years. China, as the world's largest automotive market, has also made significant efforts to develop its NEV industry. This paper aims to analyze the current situation, problems, and propose countermeasures for the development of China's NEV industry.2. Current Situation2.1 Market Size: China's NEV market has experienced rapid growth in recent years. According to statistics, the sales volume of NEVs reached X units in 20XX, accounting for X% of total vehicle sales in China.2.2 Production Capacity: The production capacity of NEVs in China has also increased significantly. By the end of 20XX, China had X NEV manufacturing enterprises with a combined production capacity of X units per year.2.3 Technological Level: China's NEV technology has made great strides, with breakthroughs in key areas such as batteries, motors, and electronic control systems. Chinese NEV manufacturers have also made significant progress in terms of energy density, battery life, and charging efficiency.3. Problems3.1 Insufficient Charging Infrastructure: The lack of charging facilities is one of the main obstacles hindering the widespread adoption of NEVs. Currently, the number of public charging stations is far from meeting the demand, leading to charging inconvenience and range anxiety for consumers.3.2 High Production Costs: The high cost of NEVs is another major hindrance to their large-scale adoption. The cost of batteries, in particular, remains high, accounting for a significant portion of the vehicle's overall cost.3.3 Lack of Consumer Acceptance: Despite government subsidies and incentives, many consumers still have reservations about NEVs. Concerns such as limited driving range, long charging times, and uncertain resale value deter potential buyers.4. Countermeasures4.1 Expanding Charging Infrastructure Network: The government should invest more in the construction of charging stations, particularly in urban areas and along major highways, to alleviate the charging problem.4.2 Increasing Government Subsidies: The government should continue to provide subsidies and incentives to reduce the purchase cost of NEVs and boost consumer acceptance.4.3 Promoting Technological Innovation: The industry should focus on research and development to improve battery technology, increase energy density, reduce costs, and enhance overall vehicle performance.4.4 Strengthening Consumer Education and Awareness: Efforts should be made to educate consumers on the benefits of NEVs, addressing their concerns and promoting their acceptance.5. ConclusionChina's NEV industry has achieved rapid growth in recent years, but still faces several challenges. By addressing the problems of insufficient charging infrastructure, high production costs, and lack of consumer acceptance, China can promote the sustainable and healthy development of its NEV industry. With the implementation of the proposed countermeasures, China's NEV industry has great potential for future growth and success.。

新能源汽车外文翻译文献(文档含英文原文和中文翻译)电动车：正在进行的绿色交通革命？随着世界上持续的能源危机，战争和石油消费以及汽车数量的增加，能源日益减少，有一天它会消失得无影无踪。

石油并不是可再生资源。

在石油消耗枯竭之前必须找到一种能源与之替代。

随着科技的发展和社会进步，电动车的发明将会有效的缓解这一燃眉之急。

电动汽车将成为理想的交通工具。

面临能源成本居高不下、消费者和政府更加重视环境保护的情况下，世界汽车制造商正加大对可替代能源性混合动力汽车技术的开发投资。

该技术能极大削减燃料消费，减少温室气体排放。

许多人把目光投向了日本和美国的汽车制造商，关心他们开发混合动力和电池电动车的进展情况。

丰田普锐斯一跃成为世界上销量最好的混合动力车。

美国的新兴汽车制造商，Tesla Motors，推出了该公司首部电池电力车，名为Tesla Roadster。

截至2010年底，通用汽车公司计划推出备受赞誉的V olt混合动力汽车，而克莱斯勒公司最近已经宣布同样的计划正在进行之中。

目前，中国在新能源汽车的自主创新过程中，坚持了政府支持，以核心技术、关键部件和系统集成为重点的原则，确立了以混合电动汽车、纯电动汽车、燃料电池汽车为“三纵”，以整车控制系统、电机驱动系统、动力蓄电池/燃料电池为“三横”的研发布局，通过产学研紧密合作，中国混合动力汽车的自主创新取得了重大进展。

形成了具有完全自主知识产权的动力系统技术平台，建立了混合动力汽车技术开发体系。

混合动力汽车的核心是电池（包括电池管理系统）技术。

除此之外，还包括发动机技术、电机控制技术、整车控制技术等，发动机和电机之间动力的转换和衔接也是重点。

从目前情况来看，中国已经建立起了混合动力汽车动力系统技术平台和产学研合作研发体系，取得了一系列突破性成果，为整车开发奠定了坚实的基础。

截止到2009年1月31日，在混合动力车辆技术领域，中国知识产权局受理并公开的中国专利申请为1116件。