电力机车弯道速度遥控--信号接收系统
电力机车弯道速度遥控-信号接收系统,电力机车,弯道,速度,遥控,信号,接收,接管,系统
河南科技学院学生姓名赵银银班级应教051指导教师杨天明论文(设计)题目电力机车弯道速度遥控信号接收系统目前已完成任务1.从图书馆、网上查找相关的资料,阅读资料,分析信号接受控制原理。根据接收发送信号以及当前电力机车弯道速度遥控的新要求,设计了电力机车弯道速度遥控的信号接收系统。电力机车弯道速度遥控包括信号发射系统、信号接收系统、单片机接收控制系统和接收报警系统。2.经比较分析知道信号接收控制系统的优缺点,在设计中还有可能出现很多问题。3.分析、掌握电力机车弯道速度遥控-信号发射系统的工作原理,及调频发射系统在机车系统中的应用。是否符合任务书要求进度:符合。尚需完成任务1.在比较分析的基础上完善单片机接受控制系统。2.设计调频接收控制系统。3.根据实际要求,依据分析的原理进行结构分析,逐步验证原理的可行性。能否按期完成论文(设计):能。存在问题和解决办法存在问题1.对现在单片机接收系统结构不了解。2.控制系统方面资料不多,接收技术应用掌握不全面。3.开始书写时内容,格式不规范,语句不符合论文要求。拟采取的办法1.查阅大量相关图书,深入了解现在调频发射器的结构。2.参考现有调频接收器原理和单片机控制系统。3.进一步学习研究调频发射技术。4.与导师、同学共同探讨、协商、寻找可靠解决问题的途径。指导教师签 字日期年 月 日教学院长(主任)意 见 负责人签字: 年 月 日本科毕业论文(设计)中期进展情况检查表 世界电力机车的发展电力机车本身的原始动机接受触网发出的电流作为能源,由机车牵引电机驱动车轮。随着电力机车功率,热效率,速度的提高,以及有力和可靠的操作过载能力成为其主要优势,但不污染环境,所以特别适用于繁忙的铁路运输和隧道,以及斜坡的山区铁路。电力机车从接触线获得电力,接触网供电电流机车都是直流和交流。根据目前的供电电流形式的不同,而不涉及电力机车本身,电力机车系统可分为基本直-直流电力机车,交-直流电力机车,交-直-交电力机车三种。直-直流电力机车采用直流电源系统,牵引变电所装有整流装置,它将成为一个三相交流-直流装置,然后访问互联网。因此,电力机车可直接从网上联络供应DC系列直流牵引电动机使用,简化了机车设备。直流系统的缺点是接触网电压低,通常l500伏或3000伏,接触线要求较粗,因此要消耗大量的有色金属,并增加建设投资。对于交-直流电力机车交流电源系统,世界上大多数国家使用的是频率(50赫兹)交换系统,或25赫兹的低频通信系统。在此电力供应系统中,牵引变电所将改为三相交流电频率的25千伏单相交流电源,然后传送到网络。但是,在电力机车上使用的字符串仍然是直流电动机(这是最大的优势:调速简单,只需改变电机端电压,因此就可以很容易地实现在较大范围内的机车速度,但这种电机由于需要使用换向器,制造和维护是非常复杂的,体积更大),这样,交流到直流机车的转变任务完成。接触网系统的直流电压没有提高很多。但接触导线的直径可以相对减少,从而减少了消费的非铁金属,但建设投资并没有减少。因此,高频通信系统已被广泛采用,世界上大多数的电力机车也开始采用交-直流方式。交-直-交流,交流非电力机车牵引电机换向器(即三相异步电动机),其在汽车制造,性能,功能,大小,重量,成本以及维护性和可靠性等方面比换向器容易得多。这是失败的电力机车,其主要的原因是提高速度相当困难。但这种机车具有优良的牵引能力。因此还是大有希望。德国制造的电力机车E120就是这种机车。电力机车的工作原理:目前的接触线和电力机车经过拱形后后重新进入断路器后,主变压器,交流牵引从主变压器绕组通过硅整流单位,分成两组,六个平行对牵引电机直流电源集中到牵引电动机的扭矩,机械能变成电能通过传动齿轮驱动的机车驱动车轮转动。电力机车的发展:首先制造了第一个标准衡量电力机车的是苏格兰人戴维森,时间是1842年。1879年5月,西弗吉尼亚州的德国西门子公司设计和制造的18撤出三个公开“乘客”电力机车,这是第一个电力机车成功的试点。1881年,法国巴黎架设第一电力架空线-电车线,它的升级,为使用高功率牵引电机创造条件:1895年,美国巴尔的摩-俄亥俄州之间的5.6公里长的隧道部分直流电气化铁路建设成功。1903年德国的三相交流电力机车创造了每小时210公里的高速记录。电力机车的发展取决于发展的电气化铁路。建立一个真正意义上的电气化铁路首先要解决如何提供高电压,改变标准的电力供应问题。目前机车接触网供电系统,分为直流系统和交流两个(交流系统包括单相交流,三相交流),其中要求电源标准。单相交流系统促进发展电气化铁路。20世纪70年代初,欧洲大陆和日本在亚洲是基本实现了交通繁忙。交通繁忙主要是铁路电气化。1973年至1974年爆发的石油危机,重新评估的经济指标是国家电力和内燃牵引的铁路,更青睐电力牵引。英国是发展的原始柴油牵引的国家,但也开始重视发展电力牵引。甚至完全靠内燃机的美国,铁路电气化的呼声也很高。到80年代初,世界上有50多个国家和地区建设电气化铁路,苏联的总长度达到了四万公里。日本,法国,西德有超过10000公里的电气化铁路。目前,世界电气化铁路已达到20多万公里。我国也加入了超过10,000公里的电气化铁路“高级俱乐部”。电气化铁路供电问题得到解决之后,发展高功率,高速的电力机车成为很多国家追求的目标。在这个时候,半导体技术和计算机控制技术的突破,促进发展催生了新的电力机车。1979年,第一高功率交流传动E120电力机车诞生于德国,为发展电力机车创了一个新时代。与提高现有电力机车速度和大力发展高速铁路相适应,发展干线电力机车开始从直流传动到交流的转变。到20世纪90年代,欧洲,日本和其他主要摩托车制造商几乎停止直流传动电力机车的生产,交流电力机车已成为世界上电力机车发展的主流。中国的电力机车:韶山I型电力机车是我国最早使用的电力机车。始于1914年,是应用于抚顺煤矿的1500 V直流电力机车。1958年我国成功地生产了第一列电力机车,从点火到一个整流器-可控硅整流器,机车不断改进,业绩提高不断,到1976年, L型作出韶山(韶山型)第131号,已基本确立。直到1989年停止生产的最后期限,SSL电力机车共有926家台湾制造商,成为我国第一个电气化铁路主要火车头。1966列SS2机车于1978年研制成功。不仅使SS3型机车牵引性能改进,而且每小时的机车功率从200kW至4千瓦,截止到1997年底,共生产了987列 ,成为第一次中国两种主要的电力机车。1985年还成功地发展了SS4型8轴货运电力机车,这是我国最大功率的电力机车(6400千瓦),已成为我国主要的重型货运机车。然后又成功继承发展SS5 , SS6和SS7型电力机车。1994年已成功地发展了速度达160公里的高速电力机车以及其他4轴电力机车。伴随着世界潮流,诞生了新的“直-交”电力机车技术。从20世纪70年代末,我国一直在进行中小型铁路功率变换器的研究。在地面上的高功率测试也在进行中,直-交流电力机车研究也已取得初步成效。发展我国电力机车始于1958年。在那个时候,铁道部第三机车厂,即现在的株洲电力机车厂在协助湘潭电机采矿电力机车制造工厂的同时,设计和编制铁路电力机车。1958年年初,该部机械工业部组织第一次访问苏联考察。在那个时候,基本定型的观念是:由于苏联使用20千伏单相交流系统60频率电力机车,因此中方决定采取25千伏单相交流系统,并且频率各不相同。所以60电力机车是一个大胆的技术改造,这相当于78个重大变化。1958年12月28日,我国第一台电力机车研制成功的铁路干线,命名“Y1-6”,机车持续功率3410千瓦,最高速度100公里/小时。到目前为止,我国干线电力机车已基本形成了4,6,8轴和3200千瓦,6400千瓦和4800千瓦幂级数。1999年5月26日,我国的株洲电力机车厂生产了第一个速度超过200公里DDJ1子弹头型电力机车,标志着我国电力牵引已跻身于国际高速列车服务行列。The Development of World Electric LocomotiveElectric locomotive itself with the original motive accept catenary sent by the current as a source of energy, from locomotive traction motor drive the wheels. With electric locomotive power, thermal efficiency, fast, strong and reliable operation Guozainaili major advantages, but do not pollute the environment, and particularly applicable to the busy railway transportation and tunnels, the slope of the mountain railway. Electric locomotive from the contact line access to electricity, catenary power supply current locomotives are both DC and AC. The current system different, not with the electric locomotive, can be divided into basically straight-DC electric locomotive, the TAC-DC electric locomotive, the TAC-Direct-AC electric locomotive three. Straight-DC electric locomotive using DC power supply system, traction substation equipped with rectifier devices, it will become a three-phase AC DC, and then to access the Internet. Therefore, the electric locomotive can be made online directly from the contact supply DC Series traction motor use, which simplifies the locomotive equipment. DC systems weaknesses are catenary low voltage, typically l500V or 3000 V, the contact wire request is rough, it is necessary to consume a large amount of non-ferrous metals, and increased construction investment. TAC - DC electric locomotive powered by AC system, most of the worlds countries use the frequency (50Hz) exchange system, or 25 Hz low-frequency communication system. In this supply system, traction substation will be changed to three-phase alternating current frequency of 25 kV single-phase AC power industry after exposure to the Internet. But in the electric locomotive used on the string is still DC motor (which is the biggest advantage motor speed as simple as changing motor terminal voltage, it should be easy to achieve in the larger context of the locomotive speed, but such Motor due to the commutator, manufacturing and maintenance are very complex, and also greater volume), the AC into DC locomotive in the task completed. The catenary system DC voltage than to raise a lot of contact wire diameter can be relatively reduced, reducing the consumption of non-ferrous metals and construction investment did not. Therefore, the frequency communication system has been widely adopted by majority of the worlds electric locomotive also pay - DC electric locomotive. TAC-Direct-exchange by exchange of non-electric locomotive traction motor commutator (that is, three-phase asynchronous motors),which is in the motor manufacturing, performance, functionality, size, weight, cost, maintenance and reliability and so on than the motor commutator much easier. It is the failure of the electric locomotive, is the main reason for speed rather difficult. This locomotive has excellent traction capacity promising. German-made electric locomotive E120 This is the locomotive. The working principle of electric locomotive, the current contact wire, and withstand electric locomotive into the arch after re-entering the circuit breaker after the main transformer, AC traction from the main transformer winding through silicon rectifier units, divided into two groups of six parallel to the traction motor DC supply concentrate to a traction motor torque, the mechanical energy into electric energy through the transmission gear-driven locomotive drive wheels turning. The development of electric locomotives: The first to create the first standard gauge electric locomotive is the Scots R Davidson, time is 1842. May 1879, the German Siemens W V design and manufacture of a 18 - to pull on the three open passenger electric locomotive, this is the first electric locomotive successful pilot. 1881, Paris, France at the first of electricity from overhead wires tram lines, which for the upgrade, using high-power traction motors to create the conditions: 1895, the United States in Baltimore - Ohio between 5.6 km long tunnel section DC electrified railway construction. 1903 Germanys three-phase AC electric locomotive created a 210 km per hour high-speed recording. Electric locomotive of development depends on the development of electrified railway. Build a real sense electrified railway is first necessary to resolve how to provide high-voltage, change standard power supply problems. Catenary locomotive current supply system, divided into DC system and the exchange of two (AC system in the single-phase AC again, three-phase AC), which called power supply standard. The frequency of the single-phase AC system to promote the development of electrified railway. 20 in the early 1970s, continental Europe and Japan in Asia is basically realized transport busy main railway electrification. 1973 1974 outbreak of the oil crisis, the national electricity and internal combustion of the railway traction re-evaluation of the economic, favored by the more electric traction. Britain is the development of the original diesel traction, but also started to attach importance to the development of electric traction. Even completely internal combustion of the United States, the voice of railway electrification also high. To the early 1980s, the world had more than 50 countries and regions to build the electrified railway, the Soviet Unions total length of electrified railway reached over 40,000 kilometers, Japan, France, West Germany have a more than 10,000 km of electrified Railway. At present, the world electrified railway has reached more than 20 million kilometres, China has also joined the more than 10,000 km of electrified railways, senior club. Electrified railway power supply problems are solved, the development of high-power, high-speed electric locomotive on a national pursuit of the goal. At this time, the semiconductor technology and computer control technology breakthroughs and promoting the development of the birth of a new electric locomotive. 1979, the first high-power AC drive E120-electric locomotive was born in Germany, opened a new era in the development of electric locomotives. With the upgrading of existing electric locomotive and the vigorous development of high-speed railway, the development of Route electric locomotive drive from DC to AC. In the 1990s, Europe, Japan and other major motorcycle manufacturers have nearly halted DC drive electric locomotive production, AC electric locomotive has become the worlds electric locomotive the mainstream of development. Chinas electric locomotive: Shaoshan an electric locomotive of Chinas earliest use of electric locomotive in 1914, is the use of the Fushun Coal Mine 1500 V DC electric locomotive. 1958 China has successfully produced the first electric locomotive, from the ignition of a rectifier to silicon rectifier, locomotives constantly improve and enhance performance, to 1976 l-made Shaoshan (SS1 type) No. 131, has been basically established. The deadline for the cessation of production in 1989, SSl electric locomotive has a total of 926 Taiwan manufacturers to become Chinas first electrified railway main locomotive. 1966 SS2 locomotive made in 1978 successfully developed SS3 locomotive not only improved traction performance, also of the hours of locomotive power from 200kW to a 4 kW 4800, deadline to the end of 1997, produced a total of 987, becoming the first Chinese two kinds of main electric locomotive. 1985 also has succeeded in the development of SS4 8 axis freight electric locomotive, it is Chinas largest electric locomotive power in a (6400 kW), has become Chinas main heavy-duty freight locomotive. After the successful development of a succession SS5, SS6 and SS7 electric locomotive. 1994 has succeeded in the development speed of 160 km of high-speed electric locomotive, and other 4-axis. World track for the new “pay-direct-diplomacy” electric locomotive new technology, from the late 1970s, China has been carrying out small and medium-sized railway power converter units on the ground and high-power test on the Hand-Direct-AC electric locomotive Research has also achieved initial success. Development of Chinas electric locomotive began in 1958. At that time, the Ministry of Railways San locomotive factory, which is now the Zhuzhou Electric Locomotive Factory in assisting the Xiangtan Electrical mining electric locomotive manufacturing plant at the same time, design and Preparation railway electric locomotive. Early 1958, the Ministry of Machinery Industry organized by the Department of the first mission to the Soviet Union study tour. At that time, the basic stereotypes of the Soviet Union is the use of 20 kV single-phase AC system 60 frequency electric locomotive, and China decided to adopt the 25 kV single-phase AC system frequency vary, so 60 electric locomotive on a bold technological transformation, which amounted to 78 major changes. December 28,1958, Chinas first electric locomotive Taiwan Railway Route Preparation successful named Y1-6.Locomotive 3410 kW continuous power, a maximum speed of 100 km / H .So far, China Route electric locomotive has been basically formed a 4,6,8 axis and 3200 kW, 6400 kW and 4800 kW power series. May 26, 1999, Chinas Zhuzhou Electric Locomotive Works produced the first speed of over 200 km DDJ1“bullet” electric locomotive, indicates that China has ranked as one of the electric traction in the international high-speed train service.毕业论文(设计)任务书题目名称 电力机车弯道速度遥控-信号接收系统学生姓名赵银银所学专业应用电子技术教育班级051指导教师姓名杨天明所学专业电气自动化职称副教授完成期限 2008年 12月 12日至 2009 年 6月 5日一、论文(设计)主要内容及主要技术指标本课题主要是利用无线电电子技术,向正在接近轨道方向运行的电力机车,以及前后方车站发射机车距离弯道的距离信号,以便于电力机车接到信号后,控制机车以适当的速度安全通过弯道。 此项技术,目前在国内尚无广泛的应用,属于民品,所以有很大的应用前景。主要技术要求:1.设计出电力机车弯道速度遥控-信号接收系统的控制线路。2.信号接收系统要具有一定的抗干扰能力。3.制作出印刷电路板。4.对线路要能够调试。二、毕业论文(设计)的基本要求1开题报告一份。2毕业设计(论文)一份;有400字左右的中英文摘要,正文后有10篇以上的参考文献,参考文献应在10篇以上,主要是期刊、杂志,少量是教材。正文中要引用5篇以上文献,并注明文献出处。论文总字数在6000字以上。3毕业设计中期检查表一份。4毕业设计总字数在10000字以上。5有不少于2000汉字的与本课题有关的外文翻译资料。三、毕业论文(设计)进度安排12008年12月25日左右,完成外文资料翻译22009年1月26日至寒假期间,完成开题报告,确定设计方案32009年3月5-11日(第1周)审核开题报告和设计方案42009年3月19日-4月15日(第2-6周)毕业设计单元部分设计。52009年4月16日-22日(第7周)毕业设计期中检查。62009年4月16日-5月13日(第7-10周)设计仿真、程序调试、电子线路调试、整理、撰写毕业设计(论文)。72009年5月14-28日(第11周)上交毕业论文,指导教师、评阅教师审查评阅论文,学生修改论文,毕业设计答辩资格审查。河南科技学院毕业论文(设计)课题审核表院(系)名称机电学院专业名称应用电子技术教育指导教师姓名及职称杨天明 副教授课题名称电力机车弯道速度遥控-信号接收系统课题来源教师研究项目立题理由和所具备的条件本课题主要是利用无线电电子技术,向正在接近轨道方向运行的电力机车,以及前后方车站发射机车距离弯道的距离信号,以便于电力机车接到信号后,控制机车以适当的速度安全通过弯道。 此项技术,目前在国内尚无广泛的应用,属于民品,所以有很大的应用前景。条件:本人已对此课题考虑较长时间,学生又是应用电子技术教育专业,学校有电机以及电子类实验室;学生可到厂里参观实习等基本条件。教研室审批意见教研室主任签字: 年 月 日毕业论文(设计)工作领导小组审批意见组长签字: 年 月 日注:本表经教务处复审后存院(系)备查。毕业论文(设计)开题报告题目名称 电力机车弯道速度遥控信号接收系统学生姓名赵银银专业应用电子技术教育班级051一、题目的意义电力机车弯道速度遥控技术是铁道部门发展的重要技术之一,它的发展直接制约着电力机车速度和运行效率的提高。近年来,随着电力、电子技术的发展以及人们对铁道部门的要求也是越来越高,电力机车的发展也取得了巨大的技术进步。在铁道部门,注重于速度的同时,电力机车运行的安全问题一直被置于首要位置。在电力机车弯道速度遥控系统中,信号接收系统主要识别和接收来自发射端的信号,并反馈给报警系统,从而向驾驶员发出警报。在电力机车将要进入弯道时,单片机接收信号后提醒司机减速,即便是司机没有察觉,也可以通过单片机接收控制系统,对电动机车进行制动控制,强行对电动机车进行减速。从而避免一切可能发生的人为故障问题,从而在提高速率的同时,把乘客的生命财产损失降到最低程度。二、国内外研究综述电力机车的普及和推广促进了该系统各项技术的突破。根据网络资源以及相关资料调查,类似本课题的项目在国内外有一定的研究成果。各种具有类似单片机接收控制系统功能的装置也就应运而生。弯道速度遥控是以MCS-51系列单片机芯片为核心。根据接收发送信号以及当前电力机车弯道速度遥控的新要求,设计了电力机车弯道速度遥控的信号接收系统,以便于电力机车能够顺利通过弯道,并且更能准确的确定电力机车现时的行程情况。这样不仅能人性化的显示出司机的操作能力,而且在司机操作失误的条件下,单片机接收控制系统更能够采用制动程序,从而更加完整的确定乘客的安全问题。三、主要研究内容1.电力机车弯道速度遥控系统电子控制线路的各个电路模块,电子器件组成及参数设置;2.根据接收信号参数设计单片机的连接方式,分析控制原理;3设计的信号接收系统要与整个弯道速度遥控系统相配合,共同完成控制功能; 4.完成整个系统线路的调试工作。四、毕业论文(设计)的研究方法或技术路线1.实际调查研究,在此基础上进探讨行分;2.通过图书馆、网络查阅相关文献资料,了解国内外发展趋势;3.与指导老师商讨以及与同组同学共同分析和探讨;4.结合所学理论知识,进行分析、研究。五、主要参考文献与资料 1刘春明,梁晋电力机车远程实时监控系统的研究2005年第12期2杨金岩,郑应强,张振仁8051单片机数据传输接口扩展技术与应用实例人民邮电出版社20053楼然苗,李光飞51系列单片机设计实例北京航空航天大学出版社20064李朝青单片机原理及接口技术M北京:北京航空航天大学出版社20055张毅刚,彭喜元等新编MCS-51单片机应用设计(第二版) 哈尔滨工业大学出版社20066朱勇机原理与应用技术清华大学出版社20067王庆有光电传感应用技术机械工业出版社20078荆文芳,史忠科计算机测量与控制2006年第11期9李炎清毕业论文写作与范例厦门:厦门大学出版社2006.10 10潭博学,苗江静集成电路原理及应用北京:电子工业出版社2003.9 11李志强,彭友云基于单片机的红外通信接口的设计200712何立民MCS-51单片机应用系统设计航空航天大学出版社200113朱定华单片机原理及接口技术电子工业出版社2001 14刘瑞新单片机原理及应用教程机械工业出版社2003六 指导教师审批意见年 月 日
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