工业型煤成型机的设计[8张CAD高清图纸和文档打包]
【温馨提示】 dwg后缀的文件为CAD图,可编辑,无水印,高清图,压缩包内文档可直接点开预览,需要原稿请自助充值下载,请见压缩包内的文件及预览,所见才能所得,请细心查看有疑问可以咨询QQ:414951605或1304139763
工业型煤成型机的设计 中 国 矿 业 大 学本科生毕业论文姓 名: 陈 会 军 学 号:0030842 学 院: 机电工程学院 专 业: 机械工程及自动化 论文题目: 工业型煤成型机的设计 专 题: 指导教师: 王忠宾 职 称: 副教授 2007年 6 月 徐州中国矿业大学毕业论文任务书学院 机电工程学院 专业年级 机自03-3班 学生姓名 陈会军 任务下达日期:2007年 3 月 5 日毕业论文日期: 2007 年 3 月 26 日 至 2007 年6 月 25日毕业论文题目: 工业型煤成型机的设计毕业论文专题题目:毕业论文主要内容和要求: 结合毕业实习采用对辊成型原理,采用强迫加料方式设计一台工业型煤成型机。 辊子转速 8-10r/min(圆周速度0.4-0.6m/s);成型压力 10-20 Kn/cm,小时产量20-30吨;型球尺寸 45*45*28, 采用液压加载;螺杆固定框架结构;同步式齿轮传动箱;1. 明确该装置的工作原理及相关受力分析,参考设计参数确定电动机功率。完成该装置的总体设计;2. 完成同步式齿轮箱装配图设计;3. 齿轮传动组件,零件工作图设计;4. 编写完成整机设计计算说明书;5. 专题讨论成型筒的材料与加工院长签字: 指导教师签字:中国矿业大学毕业论文指导教师评阅书指导教师评语(基础理论及基本技能的掌握;独立解决实际问题的能力;研究内容的理论依据和技术方法;取得的主要成果及创新点;工作态度及工作量;总体评价及建议成绩;存在问题;是否同意答辩等):成 绩: 指导教师签字: 年 月 日中国矿业大学毕业论文指导教师评阅书指导教师评语(基础理论及基本技能的掌握;独立解决实际问题的能力;研究内容的理论依据和技术方法;取得的主要成果及创新点;工作态度及工作量;总体评价及建议成绩;存在问题;是否同意答辩等):成 绩: 指导教师签字: 年 月 日中国矿业大学毕业论文评阅教师评阅书 评阅教师评语(选题的意义;基础理论及基本技能的掌握;综合运用所学知识解决实际问题的能力;工作量的大小;取得的主要成果及创新点;写作的规范程度;总体评价及建议成绩;存在问题;是否同意答辩等):成 绩: 评阅教师签字: 年 月 日中国矿业大学毕业论文答辩及综合成绩答 辩 情 况提 出 问 题回 答 问 题正 确基本正确有一般性错误有原则性错误没有回答答辩委员会评语及建议成绩:答辩委员会主任签字: 年 月 日学院领导小组综合评定成绩:学院领导小组负责人: 年 月 日摘要 本论文描述了GDC955/45对辊成型机的设计和计算过程,并对关键部位进行了分析和研究。工业对辊成型机是一种应用到型煤生产中的关键设备,属于工程机械。对辊成型机是由压辊、轴承、给料系统、承压支架、减速器(传动装置)、润滑系统、等机构组成。与传统低速重载、刚性不足的老式减速器相比,它具有体积小、重量轻、成本低廉等优点。对辊组件直接关系到型煤煤球的成球质量,工业型煤是一种广泛应用到冶金、制造化肥、电厂等工业领域、对节能、环保都具有重要意义的清洁、高效的新型燃料。本设计在对辊辊轮与对辊轴之间采用胀套无键连接技术,两对对辊辊轮之间必须具有良好的对中性,否则会影响成型质量。采用胀套无键连接的优点是可以方便的松开胀套对辊轮进行调整,保证型煤的成球率。在给料系统中,本装置采用了螺旋强迫加料装置,采用此装置可满足对辊成型机对加料速度,加料压力及物料密度的匹配要求大大提高了型煤的成球强度。本设计机架采用螺杆连接结构,此种机架制作简便,而且承载能力强,拆装方便,基本满足大型对辊成型机的工作要求。关键词:对辊成型机;工业型煤;螺旋加料;液压加载ABSTRACTThe process of the design and calculations GDC955/45 roll-type forming machine is described, and the crucial units are analyzed and investigated.Industry roll-type forming machine is a crucial device applied to the manufacturing of shape-coal. Its a kind of engineering machine. Roll-type machine consists of units such as pressing rolls, bearing, feeding system, bearing beam ,three-staged velocity-reduction gearbox (transmission system), lubricating system, and hydraulic pressing system, etc .compared conventional forming machine ,with heavy-burden and inadequate rigidity, it is of small-volume,;low-weight and low-cost.Double rolls have a direct relation to the forming-quality of shape-coal. Industry shape-coal is a new-type of clean ,effective fuel which is widely applied to various industry field such as metallurgical industry ,manufacturing industry chemical fertilizer, calcium carbide and has a vital significance to energys-aving and environment-protection business.Design in the paper uses expandedcasing and no-key connecting technology and it must be guaranteed that it must be of good centering character-istic betwween ball groves of the two rolls. Otherwise the forming quality will be seriously affected. Use expanded-casing and no-key connecting technology, rolls can can be conveniently adjusted by loosning expanded-casing to ensure the forming rate of shape coal. In the feeding system, the frequency conversion-timinghelix feeding equipment is adopted in the system which can satisfy the requriements of speed of filing the press of the feeding and the match of the material. So ,it can also improve the intensity of the figuration of the briquette.Design of structure uses construction of pressing rolls which can be easily removed or easily altered. This kind of structure is of simple-make and bear heavy loads. Hence,the working requirements os large scale roll-type forming maching are satisfied.Keywords: roll-rype forming machine; industry shape-coal; thefrequency conversion-timing helix feeding system; hydraulic loading .目 录第章 总述.11.1 对辊成型机的工作原理11.2 影响型煤成型的因素31.2.1 粉煤粒度、给配对粉煤成型的影响31.2.2 原料混合后的均匀性与搅拌时间的影响41.2.3 成型的压力41.2.4 成型过程中水分含量的影响51.2.5 压辊的直径和宽度61.2.6 两个压辊的间距61.2.7 压辊的转速61.3型轮主要参数设计理论61.3.1 最大压强71.3.2 两棍轮的间隙71.3.3 棍轮直径81.3.4 生产能力计算81.3.5 功率的计算81.4高压对辊成型机的设计及其新进展91.4.1 压辊91.4.2 压辊的支撑装置101.4.3 给料系统111.4.4 承压支架131.4.5 驱动齿轮系141.4.6 润滑141.4.7 液压施压系统14第章对辊成型机的设计过程.152.1 确定传动方案152.2 总体设计162.2.1 已知主要参数162.2.2 确定辊子的尺寸参数172.2.3 总压力计算182.2.4 辊子的驱动力矩计算192.2.5 主电机功率计算192.3 非标准同步减速器的设计202.3.1 传动比的分配202.3.2 带传动设计212.4同步减速器设计242.4.1 减速器的设计要求242.4.2 各级传动参数计算252.4.3 I级传动轮齿副设计计算262.4.4 级传动轮齿副设计计算312.4.5 级传动轮齿副设计计算372.4.6 减速器输入轴的设计和校核412.4.7 减速器输出轴的设计和校核502.4.8 型辊轴的结构设计602.4.9 轴的强度校核61第章成型机其他部分的设计.663.1型板材料的选择663.2液力加载系统分析673.2.1 液力加载系统的特征673.2.2 液力加载系统原理673.2.3 液力支撑油缸683.2.4 力加载系统受力动态分析693.3关键部位设计71参考文献.72翻译部分.74致谢.85翻译部分英文原文BELT CONVEYING SYSTEMIdeally, the system adopted for the transport of any mineral should: (a) provide continuity of mineral clearance from the point of production with maximum safety and reliability, to ensure that production is not interrupted by transport restrictions, (b) be capable of handling the peak outputs, (c) minimize degradation and dust problem , (d) eliminate spillage or at least incorporate means for its collection and reintroduction to the main mineral stream, (e) provide optimum economy in labour requirement .In general terms, belt conveying systems satisfy the above criteria. The application of remote monitoring and control. Together with the employment of bunker conveyors , further enhance the efficiency of the system.There are limiting factors affecting the use of belt conveyors in that generally a reasonably straight run is necessary, the maximum angle of inclination is normally 25 degrees (1 in 4) and the maximum lump size is to be less than about half the width of the belt. The carrying capacity is influenced by the angle of repose of the material transported, keeping in mind that passing over the idler rollers, the material is continuously disturbed and spread out on the belt. Notwithstanding the above the belt conveyor has a tremendous and expanding mineral transport potential.In its simplest form a belt conveyor consists of a pair of drums, one of which is powered, and between which is stretched an endless band. This elementary arrangement has limited use for other than short distance application such as the carrying of packages, etc. . For other than short distance the top band must be supported by regularly spaced idlers to prevent sagging. Troughing idlers are ideal for this purpose, a set of which normally consists of three separate rollers, the two outer and shorter being inclined upwards to trough the belt. For low capacity, narrow belts, two idlers may be used and for high capacity duty, five or more may be employed. The button or return belt requires a lower level of support and generally may run in a flat plane, a usual arrangement being to use single rollers, at double the spacing distance used with the top strand. With exceptionally long conveyors, two roll semi-troughed return rollers may be justified. The drive arrangements normally consist of an electric motor and speed reduction gear-box, connected to each other by suitable couplings and preferably pre-aligned on a machined bed plate, the assembly being associated with an all embracing supporting structure to support and align the idlers, pulleys and drive.The above comprise the essential elements of a typical belt conveyor; belt, idlers, pulleys, drive and structure, to which are added other important items, a selection of which will be examined, starting with probably the most important;the conveyor belt.CONVEYOR BELTING A conveyor belt that may be defined (ref. 1), as “ a number of load carrying members bonded together with polymeric compounds (making up the carcase) and protected from mechanical damage by elastomeric covers. The load carrying members usually consist of either a number of plier of woven fabric, a single solid woven fabric carcase, or a single layer of parallel, equidistant steel cables”. At the onset it must be stated that conveyor belting of any construction, may be classified as Fire Resistant or Non-fire Resistant. In certain underground situations, the former may be required by Legislation or by accepted Codes of Practice. For example, in the U.K. coal mining industry, only Approved fire resisting belting may be used underground. Most other developed countries have similar requirements. In addition there are many situations where the use of fire resistant belting is recommended, for example, in complex mineral benefication plants. It is most important that in the early stages of design of any conveyor system, the type of belt be determined, as differing characteristics of the two types may influence the design of other associated equipment, and problems may be introduced if a change is required at some later date. The use to which any particular belt is to be subjected should be covered in the purchase specification, since the various properties of a belt may need modification to accommodate the sometimes conflicting demands of coefficient of friction, ageing characteristics, moisture absorption, etc. .Also as a generality, a belt of rubber construction has a greater ability to absorb impact than one of fire resistant construction.There are three main constructional forms of belting : (a) ply construction, (b) solid woven construction, (c) steel cord construction. In the above constructions, (a) and (b), only the carcase provides the strength to carry the load and withstand the various operational stresses that are developed in the belt. Since the carcase is the most expensive element in the belt, it is important that the specification incorporates adequate means of protecting this most important element. In the(c), the load carrying steel cords requires like protection. Additionally, there is the specialised design of belt with the Cable belt system which will be separately described when that arrangement is considered.(1)Ply Belt Construction When discussing ply belting, the terms warp and weft often occur, for the purpose of this sub-section it may be taken that : warp refers to the longitudinal strength of the belt, and weft refers to the lateral strength of belt.The lateral flexibility of the belt is always of importance in order that it may conform to the idler curve, this being particularly so when deep troughing idlers are to be used.The traditional belt carcase consisted of layers of woven natural fabric, this now consists of one or more plies of synthetic fibres such as nylon and /or terylene, the whole being vulcanised or fused together with the appropriate cover material. Such synthetic fibres are stronger than natural fibres (cotton), are thinner, more flexible, allowing deeper troughing in the idlers, allow the use of smaller diameter pulleys and have a shorter elongation under high working tensions.The cover may be rubber in the case of non-fire resisting belts and PVC, Neoprene, etc. ,in the case of fire resisting types. The minimum cover on both side of any belt should be not less than 0.8 mm (0.3 in) but for the transport of almost all mineral must be increase having regard to the material handled. For example ,with moderately abrasive materials such as coal, rubble, ashes, etc. ,the minimum carrying side cover should be 2.4 mm with 0.8 mm on the pulley side. With the more abrasive minerals, see Appendix 5, the minimum carrying side over should be 3.2 mm with 1.6mm on the pulley side.Although national standards may vary, a belt type may be classified having regard to its strength, an example being given in the next sub-section.(2)Solid Woven Belt Much of that said about ply belting applies to the solid woven form , but in the later, the fibres from which the belt carcase is constructed are inter-woven, then impregnated to give a solid form, and to which appropriate covers are applied. The fibers may be of high tenacity nylon warp, cotton pile and blended weft, with certain qualities of belting employ a polyester warp. In the standard fire resisting form the cover may be PVC, but this has certain limitations, particularly in respect of conveying up inclines. To overcome this problem the cover may be of nitrile rubber, i.e. 100% butadiene acrylonitrile polymer, which offers the advantages of natural rubber. Such nitrile rubber covers are applied to both the carrying and the driving faces of the belt with consequently improved frictional characteristics which minimize load slip and afford increase driving traction. A smooth pressed finish permits more efficient belt cleaning an essential feature in view of the higher moisture content of coal and indeed many other minerals. A further advantage is that such covers do not polish in service as dose PVC . An important feature of solid woven belt is that the construction eliminates ply separation and gives excellent resistance to edge wear, further, it is rot proof and resistant to mineral oils.A modern loom to manufacture solid woven belting employs a rapier weft insertion system rather than a shuttle, to eliminate the down time require to change weft bobbins, and also to give a good selvedge finish. The weaving process finished, the carcase is transferred to the finishing process which entails impregnation with liquid PVC compound, giving an additional, appropriate wear resistant surface coating, finally being press cured under tension.In addition to satisfying U.K. requirements such belts conform to the following fire resistant specifications and are readily available in tensile strengths from 315 to 2625 kn/m of belt width: Australia MDA-Series 250 international ISO R340 Canada 4th Draft No. M422-M South Africa SABS 971France NF-M81-651 U. S .A USBM Schedule 2G Germany DIN 22103/4 A particular product range includes belts ranging in tensile warp (longitudinal ) strength ranging from 315 to 1000 kn/m, with associated warp ( lateral ) strength from 158 to 350 kN/m, the weft to warp ratio varies progressively from 50 down to 35%. Higher strength belts then increase to a tensile strength to 2625 kN/m, the weft strength remaining constant at 350 kN/m. Consequently , the weft/warp ratio drops rapidlly down to 11.4%, this being necessary to allow ready tracking in the troughing idlers. (3) Steel Cord belt Construction The ever increasing demand for higher tensile strength belting created a corresponding demand for stronger belt reinforcements, which at higher level cannot be satisfied by the use of even the highest strength man-made fibers, resulting in the use of the steel cord belt in which the warp strength is provided by steel cables. Such belt is manufactured in a two part process, (a) the mixing of ploy chloroprene to produce a centre matrix and the two cover layers , and (b) the assembly of cords , matrix and covers in a rolling process with the cords under tension, followed by a curing process. It has been found that a combination of hard (80 degrees ) fire resistant, anti-static (FRAS) elastomers and cords displaced vertically at a distance greater than 1 mm leads to the failure of the elastomer by compression and tension. Like problems may occur if there are defects in the design concept. Such problem may be overcome by the use of elastomers with a hardness in the 60 to 68 degree range-this being a stringent requirement when additives to drive ensure fire retardency are employed. Fatigue may be minimized by close attention to drive and return drum diameters and by the use of torque limitation devices in the conveyor drive. The details of the belt employed at the Sebly Mining Complex, England, are : Conveyor length 14.93 km Belt thickness 28.3 mmBelt width 1300 mm Belt strength 6590 kN/mNumber of cords 57 Vertical lift 990 m Cord diameter 13.1 mm Motor power 10100 kWDRIVING DRUMS It must be conceded that improvements in drum or pulley design has not kept pace with the overall drive-head developments. Increasingly flexible belts allow the use of smaller diameter pulleys which then rotate faster for a given belt speed. Belts themselves also run faster, resulting in yet higher rotational speed-pulleys then fail, particularly at welded connections, due to their high fatigue loading. In all stress calculations associated with drum design, explicit allowances must be made for stress ratios due to their cyclic loading. Hub deflections must be below the critical stress level and all welds should be classE. Drums should have a Fatigue Reserve Factor(FRF) of at least 1.3 to 1. the FRF being the ratio: Maximum Allowable Amplitude Stress/Actual Amplitude Stress, which should be 1.3. For infinite life-which should be objective of all drums design, a fatigue limit of not less than 108 should be specified.中文翻译:带传动系统在理想的状态下,若采用此系统对任何矿物运输时,应能(a)以最大的安全和可靠性,由间隔的生产点形成连续的矿物流,以保证生产不因运输的某些限制条件而间断。(b)能操作最高的输出,(c)使退化降到最低和减小粉尘问题,(d)消除溅射或至少把它收藏起来以及恢复主要矿产地,(e)劳工要求方面提供最佳的经济条件。一般而言,皮带传输系统符合上述的标准。应用遥感的检测和控制,连同就业掩体输送带,进一步提高了系统的效率。 这儿有许多限制因素影响带传动的使用,这是因为:它需要一个合适的直线运动,它的最大倾斜角度为25度,最大的整体尺寸要少于带宽尺寸的一半。带的运输能力受倾斜角度和皮带材料的影响,始终要记住的一点是:掠过闲人压路机,矿物质不断的干扰皮带和散布在皮带上,尽管如此,皮带还是有很大的运输潜能,从而可以扩大生产能力。一个最简单的皮带运输形式包括一对滚筒,其中一个是动力源。并且在它们之间缠绕得有无头的胶带。这种简单的缠绕方式仅限于使用在短距离输送中,比如用于搬运包裹等。除个别的短距离,顶部的胶带必须要以固定的间隔的拖棍支撑起来,防止胶带的下垂。为达到此目的,槽形的拖棍是最理想的。这种拖棍由三个独立的滚轮组成,有两个在外部,一个在离它们很近的一端,并且带从它的上面穿过。对于较低运输能力的,窄的胶带,可能使用到两个拖棍,对于高运输能力和多尘的工作环境条件下,可能用到五个或者更多的拖棍。底部或返回带需要更低的支撑条件,并且很有可能一个平面运行一般使用单一的滚轮,在双顶的间隔距离使用钢绞线。对于特定的长距离运输,两个半凹辊更为合适。 驱动部分通常由电机和齿轮减速箱组成,各个部分通过合适的联轴器联结,最好预先对齐机器底座,组装时要求所有的支撑结构支撑到拖棍并,胶带轮,且要和它对齐。 上面所讲的都是典型的皮带传输系统的必要组成元素,如:胶带,拖棍,滚筒,驱动部分,和支撑结构,在加上一些其他的部分。选定后进行审查,是开始的最重要的部分,特别是对于带式传输。运输机胶带装置 运输传送带可以定义为(参阅1)“一些承担负载运输的化合聚合物,以及避免机械遭受损坏的橡胶覆盖层。” 通常的承载部分包括一定数量的组织物,单一的固体组织物和单一的平行层及等距钢缆。 在类型方面,对于运输机胶带装置的结构材料可分为耐火和非耐火材料。在某些情况下,前者可能需要通过立法或接受守则的规定。例如,在英国煤炭开采业,只有耐火的胶带用于地下工作。其他大多数国家也都有类似的规定。另外还有许多情况下,建议使用耐火材料的胶带。例如在复杂的选矿厂。在设计任何运输机胶带装置的初期阶段,要确定胶带的类型,这是最重要的,因为两种不同类型的胶带将会影响到其他的相关的设备的设计,如果在后期需要作改变,则会有新的问题产生。使用任何特定的皮带都应该覆盖到它的采购规格,由于需要调整皮带的不同性能来满足某些摩擦要求,寿命要求以及满足吸湿的要求等。同时,作为一般性,橡胶带的冲击力吸收性要比耐火材料的吸收性好。 这里主要有三种类型结构的的胶带:(a)层芯结构,(b)整芯编织结构,(c)钢绳芯结构。 在上述的类型结构中,对于(a)类和(b)类,只有带芯承担负载和承受各种工作压力,即产生在胶带内部的压力,很重要的一点是胶带要具有各种保护能力。在(c)类中,钢丝绳芯也需要保护。 另外,有专门的皮带设计系统使用钢绳牵引胶带系统,当需要考虑不同的安排结构时,它需要分开来描述。(1)层芯结构当讨论层芯结构时,经常会遇到胶带的纵向强度和横向强度,在本小节,可以用经线来代表胶带的纵向强度,纬线来代表胶带的横向强度。胶带的横向弹性是最重要的,这是因为:它能与拖棍的曲线吻合。尤其在使用槽形的拖棍的时候。传统的带芯是由天然的橡胶材料组成的,现在的带芯由一个或多个合成纤维如尼龙/或涤纶组成,用适当的材料把整个融合在一起。这些合成纤维的强度都要比天然纤维(棉花)的强度大,要薄,更具有柔性。,允许使用在更深的槽形拖棍中,较小直径的胶带轮上, 并且在重载情况下伸缩量较小。耐火类型的胶带的覆盖层可能是橡胶,聚氯乙烯,氯丁橡胶等。胶带两边的最小覆盖层应该不少于0.8毫米(0.3英寸),但对于所有的矿物运输必须增加相关材料的处理。例如,中度磨料如煤,碎石,骨灰等,最小的运输边覆盖层应该2.4毫米,滚筒边应该是0.8 毫米。更多的磨料物质见附录5,最小的运输边覆盖层应该是3.2 毫米,滚筒边是1.6毫米。尽管各国的标准不一样,但是皮带都是根据它的强度来分的,一个给定的例子就是下面的部分。(2)整芯编织结构有许多关于整芯编织结构的说法,但对于后来的整芯编织结构,都是跨编织结构,然后用合适的层镶以坚实的形式。纤维可能是高强度尼龙纱,棉花,并贯以聚酯的胶带。标准的耐火形式的材料是聚氯乙烯,但它有一定的局限性,特别是应用在倾斜面的传输。为了克服这个缺点,覆盖层为丁腈橡胶即100%的聚丙烯腈丁二烯,与天然橡胶相比,它具有更大的优势。丁腈橡胶的覆盖层在运输面和驱动面都适用,它增加了摩擦系数和增加了驱动力。对于水分含量高的煤和其他的矿物质,胶带表面光滑是它的一个重要特征。一个最大的优势是这样的表层没有聚氯乙烯的表面光滑。整芯编织结构的胶带的一个重要特征是它的结构消除了层芯结构的缺点,并且还有良好的运载力抗磨损能力和抵抗矿物油的腐蚀。现代的的整芯编织结构是使用一把双刃剑系统而非穿梭系统。为了减少所需时间,它需要改变纬线的部分。同时也为了能整理好织边。编织过程完成后,带芯就转交给整理工艺,即使与聚氯乙烯的复合,另外在表面涂上适当的耐磨材料,最在张力下压制成型。除了满足英国的的要求外,还需要满足下述的耐火的规定和315牛顿到2625牛顿每米胶带宽的拉伸强度要求:澳洲 丙二醛系列 250 国际的国际标准组织 R340加拿大 第 4 起草号码 M422-M 的南非 SABS 971法国 NF-M81-651 U. S .A USBM 预定 2G德国 DIN 22103/4某一产品包括皮带的纵向拉伸强度分布在315千牛每米到1000 千牛每米,相关的横向拉伸强度分布在158千牛每米到350千牛每米。纵向和横向强度比列不一致,它们的比列相应的从50%降低到30%。高强度的皮带的纵向强度增加到2625千牛每米,而横向的强度仍然为350千牛每米。结果,纵横比很快的降到了11.4%,这是很有必要的的,以便满足拖棍的的轨迹。(3)钢绳芯结构随着高强度抗拉皮带的需求,便产生了相应的皮带加固要求。即在较高水平的情况下,即使是人造的最高强度的纤维也不能满足使用要求,结果便用钢绳芯结构来代替使用,它的纵向强度由钢丝绳来承担。这样的皮带的制造工艺分为两个部分,(a)聚酯混合产生一个中心层和两个覆盖层,(b)钢丝绳的组装,在张力按一个曲线过程进行轧制。已发现多种耐火材料,和防静电的弹性材料 ,并且绳索的垂直的在大于1毫米的情况下会导致弹性材料压力和张力的失效。如果存在设计缺陷,就会产生这样的问题。这些问题可以通过使用弹性体硬度在60到68度的的弹性材料来克服。在运输装置驾驶中,力矩限制装置和密切驾驶都可以减少疲劳。在英国,Sebly综采的皮带的具体参数如下:运输装置长度 1300 毫米 带厚 28.3 毫米带宽 1300 毫米 带的强度 6590 千牛每米钢丝数量 57 根 垂直举起距离 990 毫米绳索直径 13.1 毫米 电机功率 10100千瓦 驱动轮必须承认,滑轮或滚筒的设计技改进有并未跟上整个磁头的技术的发展。逐渐地,柔性的带子允许使用在较小的直径滚筒上,对于给定的带速,这个滚筒旋转得更快。皮带本身也有很快的速度,特别是在焊接处,造成高速滚筒的失效,这都归因于高疲劳负载。 所有与滚筒应力的相关设计和计算,必须明确循环应力的比例。枢纽挠度必须低于临界压力并且要求焊缝为E等级.轮的疲劳因素至少在1.3至1 之间。疲劳因素比列:最大允许应力幅值与实际应力幅值之比应该大于1.3。对于无限的寿命都是所有滚筒设计的目标。应该指出疲劳极限不少于108。
收藏