外文文献翻译参考格式

外文文献翻译格式范例本科毕业设计（外文翻译）外文参考文献译文及原文学院信息工程学院专业信息工程（电子信息工程方向）年级班别 2006级（4）班学号 3206003186学生姓名柯思怡指导教师 ______ 田妮莉 _ __2010年6月目录熟悉微软SQL Server (1)1Section A 引言 (1)2Section B 再谈数据库可伸缩性 (4)3Section C 数据库开发的特点 (7)Get Your Arms around Microsoft SQL Server (9)1Section A Introduction to SQL Server 2005 (9)2Section B Database Scalability Revisited (13)3Section C Features for Database Development (17)熟悉微软SQL Server1 Section A 引言SQL Server 2005 是微软SQL生产线上最值得期待的产品。

在经过了上百万个邮件，成百上千的规范说明，以及数十次修订后。

微软承诺SQL Server 2005 是最新的基于Windows数据库应用的数据库开发平台。

这节的内容将指出SQL Server 2005产品的一些的重要特征。

SQL Server 2005几乎覆盖OLTP及OLAP技术的所又内容。

微软公司的这个旗舰数据库产品几乎能覆盖所有的东西。

这个软件在经过五年多的制作后，成为一个与它任何一个前辈产品都完全不同的产品。

本节将介绍整个产品的大部分功能。

当人们去寻求其想要的一些功能和技术时，可以从中提取出重要的和最感新区的内容，包括SQL Server Engine 的一些蜕变的历史，以及各种各样的SQL Server 2005的版本，可伸缩性，有效性，大型数据库的维护以及商业智能等如下：●数据库引擎增强技术。

SQL Server 2005 对数据库引擎进行了许多改进，并引入了新的功能。

本科毕业设计（论文）外文翻译基本规范一、要求1、与毕业论文分开单独成文。

2、两篇文献。

二、基本格式1、文献应以英、美等国家公开发表的文献为主（Journals from English speaking countries）。

2、毕业论文翻译是相对独立的，其中应该包括题目、作者（可以不翻译）、译文的出处（杂志的名称）（5号宋体、写在文稿左上角）、关键词、摘要、前言、正文、总结等几个部分。

3、文献翻译的字体、字号、序号等应与毕业论文格式要求完全一致。

4、文中所有的图表、致谢及参考文献均可以略去，但在文献翻译的末页标注：图表、致谢及参考文献已略去(见原文)。

（空一行，字体同正文）5、原文中出现的专用名词及人名、地名、参考文献可不翻译，并同原文一样在正文中标明出处。

二、毕业论文（设计）外文翻译（一）毕业论文（设计）外文翻译的内容要求外文翻译内容必须与所选课题相关，外文原文不少于6000个印刷符号。

译文末尾要用外文注明外文原文出处。

原文出处：期刊类文献书写方法：[序号]作者（不超过3人，多者用等或et al表示）.题（篇）名[J].刊名（版本）,出版年，卷次（期次）：起止页次.原文出处：图书类文献书写方法：[序号]作者.书名[M].版本.出版地：出版者,出版年.起止页次.原文出处：论文集类文献书写方法：[序号]作者.篇名[A].编著者.论文集名[C]. 出版地：出版者，出版年.起止页次。

要求有外文原文复印件。

（二）毕业论文（设计）外文翻译的撰写与装订的格式规范第一部分：封面1.封面格式:见“毕业论文（设计）外文翻译封面”。

普通A4纸打印即可。

第二部分：外文翻译主题1.标题一级标题，三号字，宋体，顶格，加粗二级标题，四号字，宋体，顶格，加粗三级标题，小四号字，宋体，顶格，加粗2.正文小四号字，宋体。

第三部分：版面要求论文开本大小：210mm×297mm（A4纸）版芯要求：左边距：25mm，右边距：25mm，上边距：30mm，下边距：25mm，页眉边距：23mm，页脚边距：18mm字符间距：标准行距：1.25倍页眉页角：页眉的奇数页书写—浙江师范大学学士学位论文外文翻译。

本科毕业论文外文文献及译文Current situation of energy consumption and measures taken for energy saving in the iron and steel industry in China文献来源：期刊发表日期：2009.5.17学院：资源与冶金学院专业：冶金工程班级：冶金121姓名：孔博文学号：1206300131指导教师：梁铎强翻译日期：2016.6.23外文文献：Current situation of energy consumption and measures taken for energy saving in the iron and steel industry in China abstractA survey of the key issues associated with the development in the Chinese iron and steel industry and current situations of energy consumption are described in this paper. The apparent production of crude steel in China expanded to 418.78 million tonnes in 2006, which was about 34% share of the world steel production. The iron and steel industry in China is still one of the major high energy consumption and high pollution industries, which accounts for the consumption of about 15.2% of the national total energy, and generation of 14% of the national total waste water and waste gas and 6% of the total solid waste materials. The average energy consumption per unit of steel is about 20% higher than that of other advanced countries due to its low energy utilization efficiency. However, the energy efficiency of the iron and steel industry in China has made significant improvement in the past few years and significant energy savings will be achieved in the future by optimizing end-use energy utilization. Finally, some measures for the industry in terms of the economic policy of China’s 11th five-year plan are also presented.1.IntroductionThe steel industry has for long played an important role in the development of China’s economy. Over the past decades, China’s steel industry has grown rapidly, overtaken Japan, and become the world’s largest steel producer in 1996. In 2006, China’s production of crude steel amounted to 418.78 million tonnes (Mt) [1] and, continued to remain first in rank. The share of output of crude steel of about 335.17 Mt of the key producers accounted for 80% of the aggregate national production and 83.61 Mt of local producers for 20% [2]. In this paper, these key producers are the main subjects of our study.Despite these achievements, China remains a steel producer whose energy efficiency is the lowest among the major steel-producing countries, although the overall technical level of its industry has been greatly improved in line with the developments in science and technology. One typical example is the rapid adop-tion of continuous casting technology. The share of continuous casting output has increased from about 30% of all steel produced in 1992 to 95.8% in 2004. In the meantime, many large firms replaced aging blast furnaces, open-hearth furnaces, and ingot casters with large-scale, modern blast furnaces, and casting and rolling facilities. Iron making may take place either through the blast furnace process or by direct reduction and the subsequent transformation of iron into steel may be carried out either in an oxygen-blown converter or in an electric arc furnace.With improvement of the overall technical level in the steel industry, the production of iron and steel has greatly expanded in the past decade, as shown in Fig. 1 [1–4]. The apparent production of crude steel in China grew from 95 million tonnes in 1995 to 418.78 million tonnes in 2006, which is about 4.5 times that in 1995 and more than three times that in 2000 [3]. As a result, China’s share of world steel production leaped from 13% in 1995 to 34% in 2006. This growth is expected to be sustained over the next few years due to the continued growth in domestic demand.As is well known, the iron and steel industry is the industry with the largest energy consumption in the world. Having become the world’s largest steel producer since 1996 China’s steel industry has grown rapidly following huge growth in domestic demand. This increase is consistent with the trend in the increase in its energy consumption.Iron and steel production consumes large quantities of energy, especially in developing countries and countries with economies in transition where outdated and inefficient technologies are often still used. Steel production in developing countries has grown at an average annual rate of 6.6% in recent years [5] and is expected to continue to grow at similar levels due to the current low per capita steel consumption levels in these countries. In industrialized countries, steel consumption averages over 425 kg/capita, whereas even key steel-producing developing countries have extremely low average per capita consumption levels of 80 kg/capita (in 1995).Fig. 1. Crude steel production of China and share of the world from 1995 to 2006.Most of China’s steel industry developed through a system of state-owned ‘enterprises’, in which an entire community was devoted to the production of steel. As a result, the data collected relating to the energy consumed to produce steel in China also contain energy used at the enterprise level for a variety of other functional departments, both directly and indirectly related to the production of steel. In addition, part of China’s steel is produced by small steel mills that do not report energy consumption data to government statistical sources. It is important to differentiate these data so that the consumption values of China’s energy can be fairly evaluated, especially when we compare the energy consumption and energy intensity of the Chinese steel industry to those of other countries or to particular ‘best practice’examples. We note that even with these adjustments, it is possible that the data still include inaccuracies due to the issues of statistical reports.The objective of this paper is to present a survey of some of the key issues associated withthe development in the Chinese steel industry, and describes the status of its energy consumption. The differences in steel consumption in major processes and China’s role in the scene of the international steel industry are analyzed, and the outlook and the measures to be instituted for China’s iron and steel industry are also presented in the paper. It is important for the world to better understand China’s energy consumption and the use of raw materials and for China to better understand the approaches that have been developed or are being developed in other countries for more efficient use of energy and raw materials. The authors hope this paper contributes to the improved under-standing of these aspects of the industry.2.Energy consumption structure of the iron and steel industry in ChinaIt is well known that electricity production in China mainly depends on coal, and coal is also the most important fuel used in China’s iron and steel industry. In 2004, the energy consumption mix of the Chinese steel industry consisted of 69.90% coal, 26.40% electricity, 3.2% fuel oil, and 0.5% natural gas, as shown in Fig. 2 [4]. Coal is not only the most widely used fuel but is also as necessary as raw material in the iron and steel industry as most of the rest is electricity. Such a fuel structure raises the energy consumption per unit of production and is unlikely to change greatly in the near future.Fig. 2. Energy consumption mix of the steel industry of China in 2004.3. Energy consumption situation in the steel industryThe key iron and steel producers in China play an important role in its manufacture of steel and in the consumption of energy. In 2003, China’s 10 largest steel firms produced more than a third of China’s steel output, with the top four firms producing more than 20% [6]. This implies that many advanced technologies have earlier existed in China’s steel industry, but the current industry’s concentration limits the application of these technologies lowering energy efficiency in general [7]. Therefore, the iron and steel industry remains one of the highest energy consumersand pollu-tion producers accounting for about 15.2% of the national total energy consumption, 14% of the national total waste water and waste gas, and 6% of the total solid waste materials generated.Fig. 3 shows the variations in energy consumption of the key enterprises in China from 1995 to 2006 [3,8–10]. The total energy consumption of the iron and steel industry rose rapidly along with rising steel production in the past decades. In the year 2004, the total steel production of China was 274.7 Mt, rising by 107.7% compared to 2000 and by 184.2% compared to 1995 [10]. The total energy consumption of the key enterprises in China soared from 96.30 Mtce in 2000 to 197.79 Mtce in 2006, which was over twice that for 2000. However, the rising trend in energy consumption weakened in 2006, when it was 8.8% lower than that of the year before.With the application of many new technologies and equipment, the index of energy consumption per tonne of steel decreased remarkably in the past decades. The overall energy consumption for China’s large and medium producers in 2005 was 741 kgce per tonne of steel, which was 20.3% lower than that in 2000 of 930 kgce per tonne. In 2006, the overall energy consumption per tonne of steel continued to decrease to 645 kgce per tonne of steel. The comparable energy consumption also took on a decreasing trend.Fig. 3. Variation of energy consumption of the key enterprises in China from 1995 to 2006.Fig. 4. Fresh water consumption per tonne of steel from 2000 to 2005.The variations in fresh water consumption per tonne of steel from 2000 to 2006 are shown in Fig. 4 [3,10]. The total quantity of fresh water used per tonne of steel in 2006 was 6.56 m3, which is 14.9% lower than that in 2005. Other data comparing energy saving, water saving, and environmental protection between 2000 and 2005 are presented in Table 1 [10]. It can be seen that the energy efficiency of China’s iron and steel industry has made significant improvement in the past few years.4.Energy consumption situation of several main processes in the steel industryFig. 5 shows the variations in energy consumption of several major processes in the steel industry from 1995 to 2005 [3,10]. The energy consumption of the blast furnace, electric furnace and steel rolling processes has decreased remarkably since 1995, and the corresponding values for the coking, sintering, and converter furnaces have also shown minor decreases. In contrast to the years before 2001, the current energy consumption of the blast furnace process presents an increasing trend that is attributed to cost increases since 2001 in raw materials for iron making, such as coke and coal.Fig. 5. Variation of energy consumption of several main processes in the steel industry in1995–2005.Among several major processes, the energy consumption of the iron making process is markedly higher than that of other processes. Taking the example of 2004 as shown in Fig. 6, the total energy consumption of the iron making system accounted for about 70% of the total process energy consumption, including 39% for the blast furnace, 11.9% for coking, 3.51% for balling and 5.55% for sin-tering. The remaining processes accounted for a small part of about 30%, which is comprised of 12.5% for power, 7.77% for rolling steel, 17.5% for the electric furnace, and 2.22% for the converter furnace. This means that the iron making system is a key part of any energy conservation effort in the steel industry.parisons of energy consumption of the steel industry in China with international levelsEnergy consumption per tonne of steel in China is higher than that of most advanced countries. One of the reasons for this is that the energy utilization efficiency in China is low. The average energy consumption per unit of steel is about 20% higher than that of other advanced countries. Compared with Japan, for example, energy consumption for China’s large and medium firms in 2004 was 705 kgce per tonne of steel, 7.5% higher than that in Japan, which was 656 kgce per tonne. However, the energy consumption level of the small production units in Chinawas as high as 1045 kgce per tonne of steel.Fig. 6. Energy consumption structure of several main processes in the steel industry in 2004.Z.C. Guo, Z.X. Fu / Energy 35 (2010) 4356–4360The general energy efficiency of China’s steel industry is still relatively low. One of the important reasons is the existence of these small units. Table 2 shows that there is a vast difference in energy consumption between the advanced and small plants [8]. Only a few large-scale steel-makers have attained or have even exceeded the international levels. Since the output of these advanced plants cannot achieve market dominance, the average energy consumption level of China’s iron and steel industry is still embarrassing.The second reason is the existence of small-scale and decen-tralized industry in China. There are 18 plants with production capacities exceeding 5 Mt of crude steel, which accounted for 46.36% of the total national crude steel production in 2005. In Japan, the crude steel production of four largest plants accounted for 73.22% of the total national crude steel production in 2004, three of which accounted for 61.09%. Except for a few of the large-scale steel plants, China’s steel industry lags behind in technology, equipment, energy saving, environmental protection, etc. The third reason is that the low recovery and recycling efficiency of the secondary energy resources results in higher energy consumption.6.Measures and policy recommendations for the iron and steel industries of China6.1. To expand coke dry quenching technologyTraditionally, the sensible heat of hot coke, pushed from the coking chamber at the temperature of 950–1050 C, is almost equal to 35%–40% of the total amount of heat consumed in the coking process. Adopting coke dry quenching technology can enable recovery of about 80% of the sensible heat from hot coke. Besides, during dry quenching 1 tonne of hot coke can generate 0.45–0.60 tonne of steam at a pressure of about 3.9 MPa. The coke dry quenching process belongs to a technology that is energy saving, environmentally protective, and pollution-free. By using coke dry quenching, it is estimated that the rotary drum strength (M40) of coke increases by 3%–8% and the coke strength after CO2 reaction by 3%–4%. In addition, the quantity of weak binding coal input can be increased by 10% saving about 0.38 tonne of water for every tonne of coke.At the end of 2005, the proportion of coke dry quenching technology usage in China’s iron and steel industry was less than 30%. At the end of 2007, with the spread of this technology rein-forced by an independent innovation in the past two years, the proportion of usage rose to 45%. Now 34 sets of the coke dry quenching unit are under construction and the output share of coke of about 101.58 Mt produced by the coke dry quenching technology accounts for one-third of the total national production.6.2. To expand top gas pressure recovery turbine (TRT) technologyPower can be generated with the energy of pressure from the top of a blast furnace using a turbine generator group. Theoretically,the power generated from TRT equipment is equal to the power energy consumed when the coal gas pressure at the top of the blast furnace is 80 kPa. Economic returns may be obtained when the pressure of the coal gas reaches 100 kPa and even higher economic returns can be achieved, especially, if the coal gas pressure is greater than 120 kPa. In steel production by the blast furnace route, increasing the pressure at the top of the blast furnace is advanta-geous as it leads to recovery of energy resources. The amount of power generated increases by 30% if dry dust is removed at the coal gas purification stage and theturbine capacity by about 3% if the temperature of coal gas is raised by 10 C. If TRT equipment is adopted, it is estimated that 30% of energy can be recovered from the air blast for the furnace and the energy consumption in the steel making processes reduced by l l kgce/t.At the end of 2007, the blast furnaces of capacity greater than 2000 m3 in China that were equipped with TRT technology numbered 49. In future, the use of TRT technology large-scale blast furnaces in China will be widespread and vigorous.6.3. To expand the technology of pulverized coal injection for the blast furnaceUse of pulverized coal injection for blast furnaces is an impor-tant innovation for optimizing steel making systems using the blast furnace route. In addition, it is a powerful incentive to prompt the iron–steel industry to progress in many aspects such as optimizing energy structure, energy saving, reducing consumption of mate-rials, cost reduction, etc. Replacing coke by coal can ease the problem of coking coal shortage caused by energy saving measures. Besides, it can reduce environmental pollution from the coking process while also producing considerable economic returns resulting from the price difference between coal and coke.In 2007, the average quantity of pulverized coal injection employed for the blast furnace route by China’s large and medium producers was 137 kg per tonne of iron, which in 2000 was 118 kg per tonne of iron. The average quantity of injection has exceeded 200 kg per tonne of iron in some large-scale blast furnaces of China. The 4350 m3 capacity blast furnace in Bao-steel is an example. It is estimated that in 2010 the average pulverized coal injection quantity realized in China’s blast furnaces iron will be 160 kg per tonne.6.4. To eliminate low-level equipment and introduce and develop new technologyOver the past few years, the government of China made a strong effort to eliminate low-level equipment. The energy consumption of China’s small iron and steel units was 1.5 times higher than that of the large and medium producers. When China implemented its 11th five-year plan’s policy of energy saving and reducing discharge of pollutants the steel industry was restructured, its equipment capacities enhanced, and pace of modernization accelerated all ofwhich produced an enormous effect.In 2007, the number of blast furnaces with a capacity of 2000 m3 in China was 63, 17 more than that in 2005, and production capacity increased by 35%. The number of converters with a capacity of 100 tonnes was 98 in 2007, eight more than that in 2005, and production capacity increased by 8%. In 2007, the overall energy consumption, the fresh water consumption, the total emission of SO2, the total soot emission, and the total mill dust emission per tonne of steel declined by about 8%, 24%, 4.5%, 3% and 4.5%, respectively, when compared with that in 2005.In addition, China’s iron and steel industries introduced and developed actively new technologies, such as COREX and C300 melted-deoxidize technology.6.5. To create the recycling economy chain within the iron–steel industryIt is believed that three recycling economy chains could be developed in the iron–steel production process aiming at zero emission. First is recycling flue gas, which means that not only coal or coke but also flue gas will be recycled from blast furnaces, converters, or coke ovens to realize zero flue gas emission. The second is recycling industrial waste water, which means that the consumption of fresh water will be minimized and industrial waste water will be recycled using some treating equipment. The third is recycling solid waste materials. It is a comprehensive reuse process for some raw materials such as iron ores left over from the production process.China’s traditional development pattern such as large invest-ment, regardless of serious pollution and lower value-added products resulted in China’s location at the low end of the value chain of the worldwide industrial structure. It is the most impor-tant reason for China’s high consumption of energy. Compared with developed countries, China’s use of poorer quality equipment and ineffective use of process energy led to lower energy utilization efficiency.7.ProspectsWith the improvement of the overall technical level in the steel industry, the production of iron and steel has greatly expanded in the past decade. However, the iron and steel industry is still one of the major high energy consumption and high polluting industries in China. Although the energy efficiency of the iron and steel industry in China has made significant improvement in the past few years, the average energy consumption per unit of steel is about 20% higher than that of other advanced countries owing to low energy utilization efficiency, the existence of somesmall-scale and decentralized industries and low recovery and recycling efficiency of the secondary energy resources. During 2006–2010, the period of China’s 11th five-year plan, based on existing policies, measures and standards, China will promulgate and implement some new policies with more ambitious objectives of sustainable develop-ment and restructuring in the steel industry. One objective of this plan is to build a society committed to energy conservation and a pollution-free environment and to develop the recycling economy chain in the iron and steel industry. Successful implementation of current sustainable development policies and measures will result in considerable energy saving.According to this plan, China’s energy consumption per GDP in ‘China’s 11th five-year plan’will decrease by 20%, the water consumption per unit of industrial added value will decrease by 30% and the total emission of main pollutants will decrease by 10%. Some major tasks will be undertaken for some high energy consumption industries such as the iron and steel industry, nonferrous metal industry, coal industry, power sector, and chemical industry. Therefore, a new industrial path leading to the use of technology-intensive products, optimal economic efficien-cies, lower resource consumption, and less environmental pollu-tion should be forged. There will be significant energy savings by optimizing end-use energy utilization.References[1]Xie QH. The operational aspects of iron and steel industry of China in 2006 and the prospects in 2007. China Steel 2007;2:6–11 (in Chinese).[2]/cyfz/hxfx/t20070126_113627.htm[3]/economic/txt/2007-02/22/content_7852832.htm[4]Wang K, Wang C, Lu XD, Chen JN. Scenario analysis on CO2 emissions reduction potential in China’s iron and steel industry. Energy Policy 2007;35: 2320–35.[5]The Editorial Board of China steel yearbook China steel yearbook. Beijing: China Statistical Publishing House; 2004.[6]Heane A, Heste S, Gurney A, Fairhead L, Beare S, Me´lanie S, et al. New energy technologies: measuring potential impacts in APEC. APEC Energy Working Group, Report no. APEC#205–RE–01.1. Published by ABARE as Research Report 05.1, Canberra. /apec/publications/free_downloads/2005.Medialib Download.v1.html?url=/et c/medialib/apec_media_library/ downloads/workinggroups/ewg/pubs/2005.Par.0001.File.v1.1. [7]Weng YQ. Current status and prospect of energy saving and environment protection of Chinese steel industry. China Metallurgy 2003;11:1–6 (in Chinese).[8]/Info_Show.aspx?Mess_Id¼1659[9]Wang WX. Iron and steel enterprises’process energy consumption and energy saving potential. Metallurgy Management 2005;6:32–4 (in Chinese).[10]Cai JJ, He JH, Lu ZW, Li GT, Wang WX, Kong LH. Analysis of energy saving and energy consumption in Chinese steel industry for last 20 years and next 5 years. Iron and Steel 2002;37:68–73 (in Chinese).中文译文：我国钢铁工业能源消耗现状及节能对策摘要本文介绍了我国钢铁工业发展中的关键问题和能源消耗现状。

附件5 论文及外文翻译写作格式样例附录1 内封格式示例（设置成小二号字，空3行）我国居民投资理财现状及发展前景的研究（黑体，加粗，小二，居中，空2行）The Research on Status and Future of Inhabitants’Investment and Financial Management in China （Times New Roman体，加粗，小二，居中，实词首字母大写，空5行）院系经济与管理学院（宋体，四号，首行缩进6字符）专业公共事业管理（宋体，四号，首行缩进6字符）班级 6408101 （宋体，四号，首行缩进6字符）学号 200604081010 （宋体，四号，首行缩进6字符）姓名李杰（宋体，四号，首行缩进6字符）指导教师张芸（宋体，四号，首行缩进6字符）职称副教授（宋体，四号，首行缩进6字符）负责教师（宋体，四号，首行缩进6字符）（空7行）沈阳航空航天大学（宋体，四号，居中）2010年6月（宋体，四号，居中）附录2 摘要格式示例（设置成三号，空2行）摘要（黑体，加粗，三号，居中，两个字之间空两格）（空1行）我国已经步入经济全球化发展的21世纪，随着市场经济的快速增长和对外开放的进一步深化，我国金融市场发生了巨大的变化。

一方面，投资理财所涉及到的领域越来越广，不仅仅是政府、企业、社会组织进行投资理财，居民也逐步进入到金融市场中，开始利用各种投资工具对个人、家庭财产进行打理，以达到资产保值、增值，更好的用于消费、养老等的目的；另一方面，我国居民投资理财观念逐渐趋于成熟化、理性化；同时，其投资理财工具以及方式手段亦越来越向多元化、完善化发展。

本论文以我国居民投资理财为研究对象，综合运用现代经济学、金融学和管理学的理论；统计学、概率学的方法和工具，主要对我国居民投资理财的历史演变、发展现状、意识观念、存在的问题和主要投资理财工具进行了分析和探讨，并提出了改善和促进我国居民理财现状的对策和建议，指出了普通居民合理化投资理财的途径。

附12-2：毕业论文正文、文献综述和外文翻译文本编辑排版格式要求1、标题：三号宋体居中。

2、作者姓名，学号，班级小四号宋体，居中。

3、中文摘要，中文关键词。

中文摘要和关键词用小五号宋体。

其中“摘要，关键词”用黑体小五号，后面加冒号，关键词之间用分号隔开，关键词一般不超过5个。

4、正文的一级标题用四号宋体，二级标题用小四号黑体，三级标题用五号黑体，正文中文字符用五号宋体。

标题统一采用1; 1.1; 1.1.1; 2; 2.1; 2.1.2; …的样式。

标题最多为三级。

5、文中引用参考文献，统一用[1]的格式，上标。

6、参考文献用小五号字体，中文用宋体。

“参考文献”四字用宋体四号。

参考文献著录格式：序号（统一用[1]的格式）著者（如有多个作者，列出前三名，其余用“等”表示，英文用“et al”表示。

）. 文献题名[文献类型代码]（其中，专著为M，期刊为J，标准为S，学位论文为D，报告为R，论文集为C，专利为P，报刊新闻为N，论文集中析出文献为A）. 期刊名，年，卷（期）：起止页码. 其中卷加粗。

著录格式如下例：[1] 王子健,吕怡兵,王毅等. 淮河水体多介质取代苯类污染及其生态健康风险[J]. 环境科学学报, 2002,22(3): 300~304.[2] Lueking A D, Huang W, Soderstrom-Schwarz S, et al. The chemical structure of soil /sediment organic matter and its role in the sequestration and bioavailability of sorb ed organic contaminants[J]. Journal of Environment Quality, 2000,29(1):317~323. [3] 史忠宝. 建设项目环境影响评价[M]. 北京：中国环境科学出版社，1994.。

外文会议论文参考文献格式外文会议论文参考文献格式英语论文参考文献格式是什么样的大家知道吗?下面由小编为大家精心收集的外文会议论文参考文献格式，希望可以帮到大家!外文会议论文参考文献格式篇1一、英语论文参考文献的类型参考文献(即引文出处)的类型以单字母方式标识，具体如下：M——专著 C——论文集 N——报纸文章J——期刊文章 D——学位论文 R——报告对于不属于上述的文献类型，采用字母“Z”标识。

对于英文论文参考文献，还应注意以下两点：①作者姓名采用“姓在前名在后”原则，具体格式是：姓，名字的首字母. 如： Malcolm Richard Cowley 应为：Cowley, M.R.，如果有两位作者，第一位作者方式不变，&之后第二位作者名字的首字母放在前面，姓放在后面，如：Frank Norris 与Irving Gordon应为：Norris, F. & I.Gordon.;②书名、报刊名使用斜体字，如：Mastering English Literature，English Weekly。

二、参考文献的格式及举例1.期刊类【格式】[序号]作者.篇名[J].刊名，出版年份，卷号(期号)：起止页码.[1] Heider, E.R.& D.C.Oliver. The structure of color space in naming and memory of two languages[J]. Foreign Language Teaching and Research, 1999, (3): 62 –67.2.专著类【格式】[序号]作者.书名[M].出版地：出版社，出版年份：起止页码.[1] Gill, R. Mastering English Literature [M]. London: Macmillan, 1985: 42-45.3.报纸类【格式】[序号]作者.篇名[N].报纸名，出版日期(版次).4.论文集【格式】[序号]作者.篇名[C].出版地：出版者，出版年份：起始页码.[1] Spivak,G. “Can the Subaltern Speak?”[A]. In C.Nelson & L. Grossberg(eds.). Victory in Limbo: Imigism [C]. Urbana: University of Illinois Press, 1988, pp.271-313.[2] Almarza, G.G. Student foreign language teacher’s knowledge growth [A]. In D.Freeman and J.C.Richards (eds.). Teacher Learning in Language T eaching [C]. New York: Cambridge University Press. 1996. pp.50-78.5.学位论文【格式】[序号]作者.篇名[D].出版地：保存者，出版年份：起始页码.6.研究报告【格式】[序号]作者.篇名[R].出版地：出版者，出版年份：起始页码.7.条例【格式】[序号]颁布单位.条例名称.发布日期8.译著【格式】[序号]原著作者. 书名[M].译者，译.出版地：出版社，出版年份：起止页码.三、注释注释是对论文正文中某一特定内容的.进一步解释或补充说明。

英语论⽂参考⽂献标准格式英语论⽂参考⽂献标准格式 在各领域中，说到论⽂，⼤家肯定都不陌⽣吧，通过论⽂写作可以培养我们独⽴思考和创新的能⼒。

那么⼀般论⽂是怎么写的呢？以下是⼩编帮⼤家整理的英语论⽂参考⽂献标准格式，仅供参考，⼤家⼀起来看看吧。

⽤Times New Roman.每⼀条⽬顶格，如某⼀条⽬超过⼀⾏，从第⼆⾏起“悬挂缩进”2字符。

参考⽂献中所有标点与符号均在英⽂状态下输⼊，标点符号后空⼀格。

参考⽂献条⽬排列顺序：英⽂⽂献、中⽂⽂献、⽹络⽂献。

分别按作者姓⽒字母顺序排列。

⽂献前不⽤序号。

1）英⽂参考⽂献： （1）专著与编著 排列顺序为：作者姓、名、专著名、出版地、出版社、出版年。

例如： Brinkleyork: Knopf, 1993. 专著名中如果还包含其他著作或作品名，后者⽤斜体。

例如： Dunn, Richard J ed. Charlotte Bront: Jane EyreNew York: Norton, 1971. A、两个⾄三个作者 第⼀作者的`姓在前，名在后，中间⽤逗号隔开；其余作者名在前，姓在后，中间⽆逗号；每个作者之间⽤逗号隔开，最后⼀个作者的姓名前⽤“and”，后⽤句号。

例如： B、三个以上作者 第⼀作者姓名（姓在前，名在后，中间加逗号）后接“et al.”，其他作者姓名省略。

例如： University of Hawaii Press, 1997. C、同⼀作者同⼀年出版的不同⽂献，参照下例： Widdowson, Henry G1998a. Widdowson, Henry G. Cambridge: Cambridge University Press, 1998b. （2）论⽂集 参照下例： Thompson, Pett. “Modal Verbs in Academic Writing”. In Ben Kettlemann & York: Rodopi, 2002: 305-323. （3）百科全书等参考⽂献 参照下例： Fagan, Jeffrey. “Gangs and Drugs”. ork: Macmillan, 2001. （4）学术期刊论⽂ 参照下例： Murphy, Karen. “Meaningful Connections: Using Technology in Primary Classrooms”. （5）⽹络⽂献 参照下例： “Everything You Ever Wanted to Know About URL”. （6）专著： 参照下例： ⽪亚杰.结构主义[M] .北京:商务印书馆,1984. （7）期刊⽂章： 参照下例： 杨忠,张韶杰.认知语⾳学中的类典型论[J].外语教学与研究,1999,(2):1-3. （8）学位论⽂ 参照下例： 梁佳.⼤学英语四、六级测试试题现状的理论分析与问题研究[D].湖南⼤学,2002. （9）论⽂集 参照下例： 许⼩纯.含义和话语结构[A].李红儒.外国语⾔与⽂学研究[C].哈尔滨:⿊龙江⼈民出版社,1999:5-7. （10）附录 2）中⽂参考⽂献下载全⽂外⽂期刊⽹私⽴医院外⽂⽂献翻译⽂献期刊⽹。

参考文献标准格式规范（涵盖英文期刊毕业论文范例）撰写论文时，参考文献的引用和整理往往成为限速步骤。

面对冗杂繁琐的参考文献，不少科研人感到无从下手。

今天，小编给大家分享参考文献标准格式的相关内容，帮助大家快速编排好参考文献，整理思路，提炼文献精华，分分钟搞定参考文献！一、英文参考文献标准格式1.专着、论文集、学位论文、报告-[序号]主要责任者。

文献题名。

出版地：出版者，出版年。

起止页码(任选)。

示例：[1]Day,C.,Veen,D.van,& Walraven,G. Children and youth at risk and urban education. Research,policy and prac-tice. Leuven/Apeldoorn:Garant. 1997.2.期刊文章-[序号]主要责任者。

文献题名。

刊名，年，卷(期)：起止页码。

示例：[2] Driessen,G.,& Van der Grinten,M. Home language proficiency in the Netherland:The evaluation of Turkish andMoroccan bilingual programmes- A critical review,Studies in Educational Evaluation,1994,20(3)：365- 386.3.论文集中的析出文献-[序号]析出文献主要责任者。

析出文献题名。

原文献主要责任者(任选)。

原文献题名。

出版地：出版者，出版年。

析出文献起止页码。

示例：[3] Driessen,G.,Mulder,L.,& Jungbluth,P. Structural and cultural determinants of educational opportunities in theNetherlands. In S.Weil(Ed.)，Root and migration in global perspective. Jerusalem:Magnes Press.1999. pp.83- 104.[5]4.报纸文章-[序号]主要责任者。

山东建筑大学毕业论文外文文献及译文
毕业论文要求1
1. 本次发给你四个文件：论文要求1，任务书，开题报告，论文的结构建议。

2. 阅读开题报告的文献综述一栏，然后阅读相关的书籍、著作、期刊文章或网络上查阅到的文章，主要阅读你的文章中的与你的论文主题相关的内容；
3. 在3月底以前完成“外文文献及译文”内容。

查找与你的论文题目有一定关
系的著作、期刊或网络文章上的英文内容，并将英文翻译成中文。

4. 请将英文原文与你的中文翻译部分按照下面给你的参考格式完成。

格式如后
面的第2页开始到最后。

其中文献、资料来源要注明是著作、网络、期刊等的哪一种，例如，参考的格式中注明的就是著作。

5. 注意参考格式中的页眉、页脚、题目字号、字体、正文内容字体、字号。

你
撰写的外文文献要与参考格式的要求一致。

6. 外文文献部分要求字数在5000字以上。

即中文翻译内容的字数要达到5页以
上，含表格、图样等。

7. 对照论文的结构建议，查阅相应的内容，开始构思论文。

8. 外文文献及译文完成后，及时发给老师电子版。

以便审校。

老师：徐宁，
2014年3月9号
- 1 -。

广东工业大学华立学院本科毕业设计（论文）外文参考文献译文及原文系部经济学部专业经济学年级 2007级班级名称 07经济学6班学号 16020706001学生姓名张瑜琴指导教师陈锶2011 年05月目录1挑战：小额贷款中的进入和商业银行的长期承诺 (1)2什么商业银行带给小额贷款和什么把他们留在外 (2)3 商业银行的四个模型进入小额贷款之内 (4)3.1内在的单位 (4)3.2财务子公司 (5)3.3策略的同盟 (5)3.4服务公司模型 (6)4 合法的形式和操作的结构比较 (8)5 服务的个案研究公司模型：厄瓜多尔和Haiti5 (9)1 挑战：小额贷款中的进入和商业银行的长期承诺商业银行已经是逐渐重要的运动员在拉丁美洲中的小额贷款服务的发展2到小额贷款市场是小额贷款的好消息客户因为银行能提供他们一完整类型的财务的服务，包括信用，储蓄和以费用为基础的服务。

整体而言，它也对小额贷款重要，因为与他们广泛的身体、财务的和人类。

如果商业银行变成重的运动员在小额贷款，他们能提供非常强烈的竞争到传统的小额贷款机构。

资源，银行能廉宜地发射而且扩张小额贷款服务rela tively。

如果商业广告银行在小额贷款中成为严重的运动员，他们能提出非常强烈的竞争给传统的小额贷款机构。

然而，小额贷款社区里面有知觉哪一商业银行进入进入小额贷款将会是短命或浅的。

举例来说，有知觉哪一商业银行首先可能不搬进小额贷款因为时候建立小额贷款操作到一个有利润的水平超过银行的标准投资时间地平线。

或，在进入小额贷款，银行之后可能移动在－上面藉由增加贷款数量销售取利润最大值－或者更坏的事，退出如果他们是不满意与小额贷款的收益性的水平。

这些知觉已经被特性加燃料商业银行的情形进入小额贷款和后来的出口之内。

在最极端的，一些开业者已经甚至宣布，”降低尺度死！”而且抛弃了与主意合作的商业银行。

在最 signific 看得到的地方，蚂蚁利益商业银行可能带给小额贷款，国际的ACCION 发展发射而且扩张的和一些商业银行的关系小额贷款操作。

外文文献的引用格式一、APA格式1. 文献列表作者姓，名字首字母.（出版年份）. 文献. 期刊名称，卷号（期号），页码范围。

例如：Smith, J. (2020). The impact of climate change on biodiversity. Journal of Environmental Science, 35(2), 123145.2. 引用在中引用文献时，需要在相应内容后加上作者姓氏和出版年份，用括号括起来。

例如：According to Smith (2020), climate change has asignificant impact on biodiversity.二、MLA格式1. 文献列表作者姓，名字首字母. “文献.” 期刊名称，卷号（期号），页码范围，出版年份。

例如：Smith, J. “The impact of climate change on biodiversity.” Journal of Environmental Science 35, no. 2 (2020): 123145.2. 引用在中引用文献时，需要在相应内容后加上作者姓氏和页码，用括号括起来。

例如：According to Smith (123), climate change has asignificant impact on biodiversity.三、Chicago格式Chicago格式是美国芝加哥大学推荐的引用格式，广泛应用于历史、艺术、哲学等领域。

Chicago格式有两种引用方式：脚注和尾注。

具体格式如下：1. 脚注/尾注作者姓，名字首字母. 文献. 期刊名称，卷号（期号），页码范围，出版年份.例如：Smith, J. “The impact of climate change on biodiversity.” Journal of Environmental Science 35, no. 2 (2020): 123145.2. 引用在中引用文献时，需要在相应内容后加上脚注或尾注编号，如：1。

本科毕业设计（论文）外文翻译基本规范一、要求1、与毕业论文分开单独成文。

2、两篇文献。

二、基本格式1、文献应以英、美等国家公开发表的文献为主（Journals from English speaking countries）。

2、毕业论文翻译是相对独立的，其中应该包括题目、作者（可以不翻译）、译文的出处（杂志的名称）（5号宋体、写在文稿左上角）、关键词、摘要、前言、正文、总结等几个部分。

3、文献翻译的字体、字号、序号等应与毕业论文格式要求完全一致。

4、文中所有的图表、致谢及参考文献均可以略去，但在文献翻译的末页标注：图表、致谢及参考文献已略去(见原文)。

（空一行，字体同正文）5、原文中出现的专用名词及人名、地名、参考文献可不翻译，并同原文一样在正文中标明出处。

二、毕业论文（设计）外文翻译（一）毕业论文（设计）外文翻译的内容要求外文翻译内容必须与所选课题相关，外文原文不少于6000个印刷符号。

译文末尾要用外文注明外文原文出处。

原文出处：期刊类文献书写方法：[序号]作者（不超过3人，多者用等或et al表示）.题（篇）名[J].刊名（版本）,出版年，卷次（期次）：起止页次.原文出处：图书类文献书写方法：[序号]作者.书名[M].版本.出版地：出版者,出版年.起止页次.原文出处：论文集类文献书写方法：[序号]作者.篇名[A].编著者.论文集名[C]. 出版地：出版者，出版年.起止页次。

要求有外文原文复印件。

（二）毕业论文（设计）外文翻译的撰写与装订的格式规范第一部分：封面1.封面格式:见“毕业论文（设计）外文翻译封面”。

普通A4纸打印即可。

第二部分：外文翻译主题1.标题一级标题，三号字，宋体，顶格，加粗二级标题，四号字，宋体，顶格，加粗三级标题，小四号字，宋体，顶格，加粗2.正文小四号字，宋体。

第三部分：版面要求论文开本大小：210mm×297mm（A4纸）版芯要求：左边距：25mm，右边距：25mm，上边距：30mm，下边距：25mm，页眉边距：23mm，页脚边距：18mm字符间距：标准行距：1.25倍页眉页角：页眉的奇数页书写—浙江师范大学学士学位论文外文翻译。

百度文库- 让每个人平等地提升自我！外文参考文献及翻译稿的要求及格式一、外文参考文献的要求1、外文原稿应与本研究项目接近或相关联；2、外文原稿可选择相关文章或节选章节，正文字数不少于1500字。

3、格式：外文文献左上角标注“外文参考资料”字样，小四宋体。

1.5倍行距。

标题：三号，Times New Roman字体加粗，居中，行距1.5倍。

段前段后空一行。

作者（居中）及正文：小四号，Times New Roman字体，首行空2字符。

4、A4纸统一打印。

二、中文翻译稿1、中文翻译稿要与外文文献匹配，翻译要正确；2、中文翻译稿另起一页；3、格式：左上角标“中文译文”，小四宋体。

标题：宋体三号加粗居中，行距1.5倍。

段前、段后空一行。

作者（居中）及正文：小四号宋体，数字等Times New Roman字体，1.5倍行距，首行空2字符。

正文字数1500左右。

4、A4纸统一打印。

格式范例如后所示。

百度文库 - 让每个人平等地提升自我！外文参考文献Implementation of internal controls of small andmedium-sized pow erStephen Ryan The enterprise internal control carries out the strength to refer to the enterprise internal control system execution ability and dynamics, it is the one whole set behavior and the technical system, is unique competitive advantage which the enterprise has; Is a series of …………………………标题：三号，Times New Roman字体加粗，居中，行距1.5倍。

英文译著参考文献格式英文译著参考文献的格式可以根据不同的引用风格而有所不同。

以下是根据APA引用风格的标准格式示例：1. 单一作者的译著：作者姓, 作者名. (出版年). 书名 (译者名, 译). 出版地: 出版商.例如：Smith, J. (2010). The Art of Translation (Wang, L., 译). Beijing: Publishing House.2. 两位作者的译著：作者1姓, 作者1名., & 作者2姓, 作者2名. (出版年). 书名 (译者名, 译). 出版地: 出版商.例如：Johnson, M., & Anderson, P. (2015). Introduction to Translation Studies (Li, H., 译). Shanghai: University Press.3. 多位作者的译著：作者1姓, 作者1名., 作者2姓, 作者2名., & 作者3姓, 作者3名. (出版年). 书名 (译者名, 译). 出版地: 出版商.例如：Smith, J., Johnson, M., & Anderson, P. (2012). Comparative Translation Studies (Wu, Y., 译). Beijing: Publishing House.4. 编辑的译著：编者姓, 编者名. (Ed.). (出版年). 书名 (译者名, 译). 出版地: 出版商.例如：Brown, A. (Ed.). (2008). Translation and Language Teaching (Zhang, L., 译). Shanghai: University Press.需要注意的是，以上的格式是根据APA引用风格的标准来给出的示例，其他引用风格（如MLA、Chicago等）可能会有稍微的差异。

嘉兴学院毕业论文（设计）外文翻译撰写格式规范一、外文翻译形式要求1、要求本科生毕业论文（设计）外文翻译部分的外文字符不少于1.5万字, 每篇外文文献翻译的中文字数要求达到2000字以上，一般以2000~3000字左右为宜。

2、翻译的外文文献应主要选自学术期刊、学术会议的文章、有关著作及其他相关材料，应与毕业论文（设计）主题相关，并作为外文参考文献列入毕业论文（设计）的参考文献。

3、外文翻译应包括外文文献原文和译文，译文要符合外文格式规范和翻译习惯。

二、打印格式嘉兴学院毕业论文（设计）外文翻译打印纸张统一用A4复印纸，页面设置：上：2.8；下：2.6；左：3.0；右：2.6；页眉：1.5；页脚：1.75。

段落格式为：1.5倍行距，段前、段后均为0磅。

页脚设置为：插入页码，居中。

具体格式见下页温馨提示：正式提交“嘉兴学院毕业论文（设计）外文翻译”时请删除本文本中说明性的文字部分（红字部分）。

嘉兴学院本科毕业论文（设计）外文翻译题目：（指毕业论文题目）学院名称：服装与艺术设计学院专业班级：楷体小四学生姓名：楷体小四一、外文原文见附件（文件名：12位学号+学生姓名+3外文原文．文件扩展名）。

二、翻译文章翻译文章题目（黑体小三号，1.5倍行距，居中）作者（用原文，不需翻译，Times New Roman五号，加粗，1.5倍行距，居中）工作单位（用原文，不需翻译，Times New Roman五号，1.5倍行距，居中）摘要：由于消费者的需求和汽车市场竞争力的提高，汽车检测标准越来越高。

现在车辆生产必须长于之前的时间并允许更高的价格进行连续转售……。

(内容采用宋体五号，1.5倍行距)关键词：汽车产业纺织品，测试，控制，标准，材料的耐用性1 导言（一级标题，黑体五号，1.5倍行距，顶格）缩进两个字符，文本主体内容采用宋体（五号），1.5倍行距参考文献（一级标题，黑体五号， 1.5倍行距，顶格）略（参考文献不需翻译，可省略）资料来源：AUTEX Research Journal, V ol. 5, No3, September 2008*****译****校（另起一页）三、指导教师评语***同学是否能按时完成外文翻译工作。

外文文献翻译格式要求
外文文献中文翻译的格式要求通常包括以下几个方面：
2.翻译稿的标题应与原文保持一致，通常在文献翻译稿的第一页的中间位置，使用加粗、居中排版。

3.每一段落开始时空两行，段落间距可以根据需要适当调整。

4. 翻译稿中的引用部分，应在文中用中括号标注原文引用部分的位置，如 "[Original text]"
5.翻译稿中的图表、表格等内容，需要在相应位置插入，并在上方标明图表或表格编号，并在下方进行说明。

7.在翻译稿的最后，需要标注翻译人员的签名，并附上日期。

总之，翻译稿与原文应尽量保持一致，在排版和格式上遵循一定的要求和规范。

具体格式要求也可以根据翻译机构或期刊的要求进行调整。

如何在论文中正确引用外文文献与翻译原则在撰写学术论文时，引用外文文献是非常重要的一环。

正确引用外文文献不仅能够提升论文的可信度和学术价值，还有助于读者深入了解相关研究领域。

然而，由于语言和文化的差异，正确引用外文文献并进行准确翻译是一项具有挑战性的任务。

本文将介绍在论文中正确引用外文文献的方法和翻译原则。

首先，在引用外文文献时，我们应该遵循一些基本的引用规范。

一般来说，引用外文文献需要提供作者姓名、文章标题、期刊名称或书名、出版年份、卷号和页码等信息。

在引用外文期刊文章时，一般遵循的格式是：作者姓名. 文章标题[J].期刊名称, 出版年份, 卷号(期号): 页码。

而在引用外文书籍时，一般遵循的格式是：作者姓名. 书名[M]. 出版地: 出版社, 出版年份。

其次，正确翻译外文文献也是十分重要的。

在翻译外文文献时，我们应该尽可能保持原文的准确性和完整性。

首先，我们需要确保对原文的理解准确无误。

如果在理解上存在困难，可以参考词典或咨询专业人士的意见。

其次，我们需要注意翻译的语言风格和表达方式。

在翻译过程中，应该尽量避免使用生硬的直译，而要根据上下文和语境进行灵活翻译，使得翻译后的文献更符合中文读者的阅读习惯和理解能力。

在进行文献翻译时，还需要注意一些特殊情况。

首先，对于外文文献中的专有名词和术语，应该尽量保持原文的表达方式。

如果需要翻译，可以在括号中加上对应的中文释义。

其次，对于外文文献中的缩写词和首字母缩写，应该在首次出现时给出完整的解释，并在后续引用中使用缩写形式。

此外，还需要注意对于外文文献中的引用和注释的翻译。

在翻译时，应该尽量保持原文的引用格式和注释方式，以便读者能够准确理解和查找相关资料。

除了正确引用外文文献和准确翻译外文文献外，我们还需要注意一些其他细节。

首先，应该尽量选择权威和可靠的外文文献进行引用。

在选择外文文献时，可以参考相关专业数据库、期刊和书籍推荐等渠道。

其次，应该注意引用外文文献的数量和质量。

20外⽂⽂献翻译原⽂及译⽂参考样式华北电⼒⼤学科技学院毕业设计（论⽂）附件外⽂⽂献翻译学号： 0819******** 姓名：宗鹏程所在系别：机械⼯程及⾃动化专业班级：机械08K1指导教师：张超原⽂标题：Development of a High-PerformanceMagnetic Gear年⽉⽇⾼性能磁齿轮的发展1摘要：本⽂提出了⼀个⾼性能永磁齿轮的计算和测量结果。

上述分析的永磁齿轮有5.5的传动⽐，并能够提供27 Nm的⼒矩。

分析表明，由于它的弹簧扭转常数很⼩，因此需要特别重视安装了这种⾼性能永磁齿轮的系统。

上述分析的齿轮也已经被应⽤在实际中，以验证、预测其效率。

经测量，由于较⼤端齿轮传动引起的磁⼒齿轮的扭矩只有16 Nm。

⼀项关于磁齿轮效率损失的系统研究也展⽰了为什么实际⼯作效率只有81％。

⼀⼤部分磁损耗起源于轴承，因为机械故障的存在，此轴承的备⽤轴承在此时是必要的。

如果没有源于轴的少量磁泄漏，我们估计能得到⾼达96％的效率。

与传统的机械齿轮的⽐较表明，磁性齿轮具有更好的效率和单位体积较⼤扭矩。

最后，可以得出结论，本⽂的研究结果可能有助于促进传统机械齿轮向磁性齿轮发展。

关键词：有限元分析（FEA）、变速箱，⾼转矩密度，磁性齿轮。

⼀、导⾔由于永久磁铁能产⽣磁通和磁⼒，虽然⼏个世纪过去了，许多⼈仍然着迷于永久磁铁。

，在过去20年的复兴阶段，正是这些优点已经使得永久磁铁在很多实际中⼴泛的应⽤，包括在起重机，扬声器，接头领域，尤其是在永久磁铁电机⽅⾯。

其中对永磁铁的复兴最常见于效率和转矩密度由于永磁铁的应⽤显著提⾼的⼩型机器的领域。

在永久磁铁没有获取⾼度重视的⼀个领域是传动装置的领域，也就是说，磁⼒联轴器不被⼴泛⽤于传动装置。

磁性联轴器基本上可以被视为以传动⽐为1：1磁⼒齿轮。

相⽐标准电⽓机器有约10kN m/m的扭矩，装有⾼能量永久磁铁的磁耦有⾮常⾼的单位体积密度的扭矩，变化范围⼤约300–400 kN 。

外文文献翻译格式
外文文献翻译格式一般需包括以下内容：
1. 文献翻译的题目：对外文文献的标题进行翻译，并在翻译后的题目前加上“外文文献翻译：”。

2. 文献的出处：包括外文文献的作者名称、文献标题、原文出版信息等。

3. 翻译的正文：按照文章的段落，将外文文献逐段翻译成中文。

在翻译的文本前后加上序号，以示区分。

4. 翻译的语言风格：外文文献翻译应注重语言风格的保持。

翻译时要根据文章的风格，选择适当的中文表达方式，保持原文的句子结构和词汇用法。

5. 原文和译文对照：将原文和译文对照排列，方便读者对照阅读。

可以将原文和译文分别排列在左右两栏中，或者将原文和译文分别放在不同的页面上，便于对照阅读。

6. 翻译中的注释：如果有部分内容翻译困难或有待解释的地方，在翻译文中添加注释。

注释的格式一般为在译文后面加上方括号，括号内的文字为注释内容。

7. 译者的信息：在文献翻译末尾一般会加上译者的姓名，并注明译者的专业领域或者工作单位。

总之，外文文献翻译格式需要将原文翻译成中文，保持原文的结构和风格，并加上适当的注释和对照，方便读者阅读和理解。

外文文献翻译格式要求：（1）摘要，关键词：宋体五号（其中“摘要”和“关键词”为宋体五号加粗），行间距设置为18磅，段前段后间距设置为0.5行，对齐方式选择“两端对齐”方式；各个关键词之间以分号（；）或者（，）隔开，最后一个关键词后不加标点；（2）正文一级标题：采用黑体小三号加粗，行间距设置为20磅，段前段后间距设置为0.5行，一般采用“1 引言”样式，其中1和“引言”之间用一个空格分开；正文二级标题：采用黑体小三号，行间距设置为20磅，段前段后间距设置为0.5行，一般采用“2.1 系统原理”样式，其中1和“系统原理”之间用一个空格分开；；一级标题和二级标题采用“左对齐”方式；（3）正文内容：采用宋体小四号，行间距设置为20磅，段前段后间距设置为0行，首行缩进2字符，正文对齐方式在段落格式设置中选择“两端对齐”，遇正文中有公式的，设置该行（段）行间距为“单倍行距”（4）插图：请设置图片版式为“浮于文字上方”，并勾选“居中”，图片大小根据版面，按比例适当进行缩放，图示说明采用“图1 主控制器的结构图”样式置于图下，图序与说明以一个空格字符间隔，图示说明采用宋体五号，居中对齐，行间距设置为“单倍行距”，段前段后距设置为0.5行；（5）表格：在表格属性中选择“居中”对齐方式，表格说明采用“表1 两种方法试验数据比较”样式置于表格上方，表序与说明以一个空格字符间隔，表格说明采用宋体五号，居中对齐，行间距设置为“单倍行距”，段前段后距设置为0.5行；（6）参考文献：“参考文献”格式同一级标题格式，参考文献内容采用宋体五号，行间距设置为18磅，段前段后间距设置为0行，对齐方式选择“左对齐”方式，其中出现的标点一律采用英文标点；以上摘要，关键词，正文，标题及参考文献中出现的英文字符和数字，一律设置为“Times New Roman”字体。

另外：外文文献翻译附于开题报告之后：第一部分为译文，第二部分为外文文献原文，译文与原文均需单独编制页码（底端居中）并注明出处。