道路工程毕业设计外文翻译---公路线形设计.docx

上传人:h**** 文档编号:26677870 上传时间:2022-07-18 格式:DOCX 页数:20 大小:21.13KB
返回 下载 相关 举报
道路工程毕业设计外文翻译---公路线形设计.docx_第1页
第1页 / 共20页
道路工程毕业设计外文翻译---公路线形设计.docx_第2页
第2页 / 共20页
点击查看更多>>
资源描述

《道路工程毕业设计外文翻译---公路线形设计.docx》由会员分享,可在线阅读,更多相关《道路工程毕业设计外文翻译---公路线形设计.docx(20页珍藏版)》请在taowenge.com淘文阁网|工程机械CAD图纸|机械工程制图|CAD装配图下载|SolidWorks_CaTia_CAD_UG_PROE_设计图分享下载上搜索。

1、道路工程毕业设计外文翻译-公路线形设计 大学毕业设计(论文) 公路线形设计 A.平面设计 道路的线形反映在平面图上是由一系列的直线和与直线相连的圆曲线构成的。现代设计时常在直线与圆曲线之间插入缓和曲线。 线形应是连续的,应避免平缓线形到小半径曲线的突变或者长直线末端与小半径曲线相连接的突然变化,否则会发生交通事故。同样,不同半径的圆弧首尾相接(复曲线)或在两半径不同的圆弧之间插入短直线都是不良的线形,除非在圆弧之间插入缓和曲线。长而平缓的曲线总是良好的线形,因为这种曲线线形优美,将来也不会废弃。然而,双向道路线形全由曲线构成也是不理想的,因为一些驾驶员通过曲线路段时总是犹豫。长而缓的曲线应用在

2、拐角较小的地方。如果采用短曲线,则会出现“扭结”。另外,线路的平,纵断面设计应综合考虑,而不应只顾其一,不顾其二,例如,当平曲线的起点位于竖曲线的顶点附近时将会产生严重的交通事故。 行驶在曲线路段上的车辆受到离心力的作用,就需要一个大小相同方向相反的由超高和侧向摩擦提供的力抵消它,从公路设计的角度看,超高或横向摩擦力都不能超过某一最大值,这些控制值对于某一规定设计车速可能采用曲线的曲率作了限制。通常情况下,某一圆曲线的曲率是由其半径来体现的。而对于线形设计而言,曲率常常通过曲度来描述,即100ft长的曲线所对应的中心角,曲度与曲线的半径成反比。 公路的直线地段设置正常的路拱,而曲线地段则设置超

3、高,在正常断面与超高断面之间必须设置过度渐变路段。通常的做法是维持道路每一条中线设计标高不变,通过抬高外侧边缘,降低内侧边缘以形成超高,对于直线与圆曲线直接相连的线形,超高应从未到达曲线之前的直线上开始,在曲线顶点另一端一定距离以外达到全部超高。 如果车辆以高速度行驶在一段受限制的路段,如直线与小半径的圆曲线相连,行车会极不舒服。汽车驶进曲线路段时,超高开始,车辆向内侧倾斜,但乘客须维持身体的垂直状态,因为此时未受到离心力的作用。当汽车到达曲线路段时,离心力突然产生,迫使乘客须作进一步的姿势调整。当汽车离开曲线时,上述过程刚好相反。插入缓和曲线后,半径从无穷大逐渐过渡到圆曲线上的某一固定值,离

4、心力逐渐增大,沿缓和曲线精心设置超高,离心力平缓逐渐增加,避免了行车颠簸。 大学毕业设计(论文) 缓和曲线在铁路上已经使用多年,但在公路上最近才得以应用,这可以理解。火车必须遵循精确的运行轨道,只有采用缓和曲线后,上述那种不舒服的感觉才能消除。然而,汽车司机在公路上可以随意改变侧向位置,通过迂回进入圆曲线来为自己提供缓和曲线。但是在一个车道上(有时在其他车道上)做这种迂回行驶是非常危险的。设计合理的缓和曲线使得上述迂回没有必要。多丛安全为计,公路广泛采用缓和曲线。 对于半径相同的圆曲线来说,在末端加上缓和曲线就会改变曲线和直线的相关位置,因此,应在最终定线勘测之前应决定是否采用缓和曲线。一般曲

5、线的起点标为PC或BC,终点标为PT或EC。对含有缓和曲线的曲线,通常的标记配置为:TC,SC,CS和ST。 对于双向道路,急弯处应增加路面宽度,这主要基于以下因素:1.驾驶员害怕驶出路面边缘;2.由于车辆前轮和后轮的行驶轨迹不同,车辆有效横向宽度加大;3.车辆前方相对于公路中线倾斜而增加的宽度。对于宽度为24ft 的道路,增加的宽度很小,可以忽略。只有当设计车速为30mil/h,且曲度可达2ft然而,对于较窄的路面,即便是在较平缓的曲线路段上,加宽也是很重要的,推荐加宽值及加宽设计见公路线形设计。 B.纵坡线 公路的竖向线形及其对车连运行的安全性和经济性的影响构成了公路设计中最重要的要素之一

6、。竖向线形由直线和竖向抛物线或圆曲线组成,称为纵坡线。纵坡线从水平线逐渐上升时称为上坡,反之,则称为下坡。在分析坡度与坡度控制中,设计人员通常要研究中线纵断面上坡度变化的影响。 在确定坡度时,最理想的情况是挖方和填方平衡,没有大量的借方和弃方。所有的运土都尽可能下坡运并且距离不长,坡度应随地形而变,并且与既有排水系统的升,降方向一致。在山区,坡度要使得挖填平衡以使总成本最低。在平原或草原地区,坡度与地表近似平行,但高于地表足够的高度,以利于路面排水,若有必要,可利用风力来清除表面积雪。如公路接近或沿河流走行,纵坡现的高度由预期洪水位来决定。无论在何种情况下,平缓的坡度现要比由短直线段连接短竖曲

7、线构成的不断变向的坡度线好得多。 由上坡向下坡变化的路段应设在挖方路段,而由下坡向上坡变化的路段应设在填方路段。这样的线形设计较好往往可以避免形成与现状地貌相反的土堆或是凹地。在挖填方平衡相比,在确定纵坡线时,其他考虑则重要得多。 城市项目往往比农村项目要求对控制要素进行更详尽的研究,对高程进 大学毕业设计(论文) 行更细致的调整。一般来说,设计与现有条件相符的坡度较好,这样可避免一些不必要的花费。 在坡度的分析和控制中,坡度对机动车运行费用的影响是最重要的考虑因素之一。坡度增大,油耗显然增大,车速就要减慢。一个较为经济的方案则可使坡度减小而增加的年度成本与坡度不减而增加的车辆运行年度成本之间

8、相平衡。这个问题的准确解决方法取决于对交通流量和交通类型的了解,这只有通过交通调查方能获知。 在不同的州,最大纵坡也相差悬殊,AASHTO建议由时间车速和地形来选择最大纵坡。现行设计以设计车速为70mil/h时最大纵坡为5%,设计车速30mil/h时,根据地形不同,最大纵坡一般为7%-12%。 当采用较长的持续爬坡时,在没有为慢行车辆提供爬坡道时,坡长不能够超过临界坡长。临界坡长可从3%纵坡的1700ft变化至8%纵坡的500ft。 持续长坡的坡度必须小于公路任何一个端面的最大坡度,通常将长的持续单一纵坡断开,设计成低部为一陡坡,而接近坡顶则让坡度减小。同时要避免由于纵断面倾斜而造成的视野受阻

9、。 高速公路的最大纵坡为9%,只有当路面排水成问题时,如水必须排至边沟或排水沟,最小坡度标准才显示起重要性。这种情况下,AASHTO建议最小坡度为0.35%。 C.视距 为保证行车安全,公路设计必须似的驾驶员视线前方有足够的一段距离,使他们能够避让以外的障碍物,或者安全地超车。视距就是车辆驾驶员前方可见的公路长度。安全视距具有两方面含义:“停车视距”或“不超车视距”或“超车视距”。 有时,大件物体也许会掉到路上,会对撞上去的车辆造成严重的危害。同样,轿车或卡车也可能会被一溜车辆阻在车道上。无论是哪种情况发生,合理设计要求驾驶员在一段距离以外就能看见这种险情,并在撞上去之前把车刹住。此外,认为车

10、辆通过离开所行驶的车道就可以躲避危险的想法是不安全的。因为这会导致车辆失控或是与另一辆车想撞。 停车视距由两部分组成:第一部分是当驾驶员发现障碍物而作出制动之前驶出的一段距离,在这一察觉与反应阶段,车辆以其初始速度行驶;第二部分是驾驶员刹车后车辆所驶过的一段距离。第一部分停车视距取决于车速及驾驶员的察觉时间和制动时间。第二部分停车视距取决于车速,刹车,轮 大学毕业设计(论文) 胎,路面的条件以及公路的线形和坡度。 在双车道公路上,每间隔一定距离,就应该提供超越慢行车辆的机会。否则,公路容量将降低,事故将增多,因为急燥的驾驶员在不能安全超车时冒着撞车危险强行超车,能被看清的容许安全超车的前方最小

11、距离叫做超车视距。 驾驶员在做出是否超车的决定时,必须将前方的能见距离与完成超车动作所需的距离对比考虑。影响他做出决定的因素是开车的小心程度和车辆加速性能。由于人与人的显著差别,主要是人的判断和动作而不是力学定理决定的超车行为随着驾驶员的不同而大不相同。为了确立超车视距值,工程人员观察了许多驾驶员的超车行为。在1938-1941年间,进行了建立超车视距标准的基本调查。假设操作条件如下: 1.被超车辆匀速行驶。 2.超车在进入超车区时减速行驶在被超车后。 3.当到达超车区时,驾驶员需一短时间来观察超车区,并开始超车。 4.面对相向车辆,在一个延迟的启动和一个匆忙的拐弯的动作中,完成 超车。在超车

12、过程中,超车在超车道上加速,起平均速度比被超车快10mil/h。 5.当超车返回到它原来的车道上时,在它与另一车道上的相向车辆之间 必须有一定的安全距离。 以上五项之和就是超车视距。 附录2 Geometric Design of Highways A. Alignment Design The alignment of a road is shown on the plane view and is a series of straight lines called tangents connected by circular curves. In modern practice it is

13、 common to interpose transition or spiral curves between tangents and circular curves. Alignment must be consistent. Sudden change from flat to sharp curves and long tangents followed by sharp curves must be avoided; otherwise, accident hazards will be created. Likewise, placing circular curves of d

14、ifferent radii end to end (compound curves) or having a short tangent between two curves is poor practice unless suitable transitions between them are provided. Long, flat curves are preferable at all times, as they are pleasing in appearance and decrease possibility of future obsolescence. However,

15、 alignment without tangents is undesirable on two-lane roads because some drivers hesitate to pass on curve. Long, flat curves should be used for small changes in direction, as short curves appear as “kink?. Also horizontal and vertical alignment must be considered together, not separately. For exam

16、ple, a sharp horizontal curve beginning near a crest can create a serious accident hazard.” A vehicle traveling in a curved path is subject to centrifugal force. This is balanced by an equal and opposite force developed through superelevation and side friction. Form a highway design standpoint, both

17、 superelevation and side friction cannot exceed certain maximums, and these controls place limits on the sharpness of curves that can be used with a design speed. Usually the sharpness of a given circular curve is indicated by its radius. However, for alignment design, sharpness is commonly expresse

18、d in terms of degree of curve, which is the central angle subtended by a 100-ft length of curve. Degree of curve is inversely proportional to the radius. Tangent sections of highways carry normal cross slope; curved sections are superelevated. Provision must be made for gradual change from one to th

19、e other. This usually involves maintaining the center line of each individual roadway at profile grade while raising the outer edge and lowering the inner edge to produce the desired superelevation. Where the alignment consists of tangents connected by circular curves, introduction of superelevation

20、 is begun on tangent before the curve is reached, and full superelevation is attained some distance beyond the point of curve. If a vehicle travels at high speed on a carefully restricted path made up of tangents connected by sharp circular curve, riding is extremely uncomfortable. As the car approa

21、ches a curve, superelevation begins and the vehicle is tilted inward, but the passenger must remain vertical since there is no centrifugal force requiring compensation. When the vehicle reaches the curve, full centrifugal force develops at once, and pulls the rider outward from his vertical position

22、. To achieve a position of equilibrium he must force his body far inward. As the remaining superelevation takes effect, further adjustment in position is required. This process is repeated in reverse order as the vehicle leaves the curve. When easement curves are introduced, the change in radius fro

23、m infinity on the tangent to that of the circular curve is effected gradually so that centrifugal force also develops gradually. By careful application of superelevation along the spiral, a smooth and gradual application of centrifugal force can be had and the roughness avoided. Easement curves have

24、 been used by the railroads for many yeas, but their adoption by highway agencies has come only recently. This is understandable. Railroad trains must follow the precise alignment of the tracks, and the discomfort described here can be avoided only by adopting easement curves. On the other hand, the

25、 motor-vehicle operator is free to alter his lateral position on the road and can provide his own easement curve by steering into circular curves gradually. However, this weaving within a traffic lane (but sometimes into other lanes) is dangerous. Properly designed easement curves make weaving unnec

26、essary. It is largely for safety reasons, then, that easement curves have been widely adopted by highway agencies. For the same radius circular curve, the addition of easement curves at the ends changes the location of the curve with relation to its tangents; hence the decision regarding their use s

27、hould be made before the final location survey. They point of beginning of an ordinary circular curve is usually labeled the PC (point of curve) or BC (beginning of curve). Its end is marked the PT (point of tangent) or EC (end of curve). For curves that include easements, the common notation is, as

28、 stationing increases: TS (tangent to spiral), SC (spiral to circular curve), CS (circular curve to spiral), and ST (spiral to tangent). On two-lane pavements provision of a wilder roadway is advisable on sharp curves. This will allow for such factors as the tendency for drivers to shy away from the

29、 pavement edge, increased effective transverse vehicle width because the front and rear wheels do not track, and added width because of the slanted position of the front of the vehicle to the roadway centerline. For 24-ft roadways, the added width is so small that it can be neglected, Only for 30mph

30、 design speeds and curves sharper than 22does the added width reach 2 ft. For narrower pavements, however, widening assumes importance even on fairly flat curves, Recommended amounts of and procedures for curve widening are given in Geometric Design for Highways. B. Grades The vertical alignment of

31、the roadway and its effect on the safe and economical operation of the motor vehicle constitute one of the most important features of road design. The vertical alignment, which consists of a series of straight lines connected by vertical parabolic or circular curves, is known as the “grade line.” Wh

32、en the grade line is increasing from the horizontal it is known as a “minus grade.” In analyzing grade controls, the designer usuall y studies the effect of change in grade on the centerline profile. In the establishment of a grade, an ideal situation is one in which the cut is balanced against the

33、fill without a great deal of borrow or an excess of cut to be wasted. All hauls should be downhill if possible and not to long. The grade should follow the general terrain and rise and fall in the direction of the existing drainage. In mountainous country the grade may be set to balance excavation a

34、gainst embankment as a clue toward least overall cost. In flat or prairie country it will be approximately parallel to the ground surface but sufficiently above it to allow surface drainage and, where necessary, to permit the wind to clear drifting snow. Where the road approaches or follows along st

35、reams, the height of the grade line may be dictated by the expected level of flood water. Under all conditions, smooth, flowing grade lines are preferable to choppy ones of many short straight sections connected with short vertical curves. Changes of grade from plus to minus should be placed in cuts

36、, and changes from a minus grade to a plus grade should be placed in fills. This will generally give a good design, and many times it will avoid the appearance of building hills and producing depressions contrary to the generally give a good design, and many times it will avoid the appearance of bui

37、lding hills and producing depressions contrary to the general existing contours of the land. Other considerations for determining the grade line may be of more importance than the balancing of cuts and fills. Urban projects usually require a more detailed study of the controls and finer adjustment o

38、f elevations than do rural projects. It is of best to adjust to grade to meet existing conditions because of the additional expense of doing otherwise. In the analysis of grade and grade control, one of the most important considerations is the effect of grades on the operating costs of the motor veh

39、icle. An increase in gasoline consumption and a reduction in speed are apparent when grades are increased. An economical approach would be to balance the added annual cost of grade reduction against the added annual cost of vehicle operation without grade reduction. An accurate solution to the probl

40、em depends on the knowledge of traffic volume and type, which and be obtained only be means of a traffic survey. While maximum grades vary a great deal in various states, AASHTO recommendations make maximum grades dependent on design speed and topography. Present practice limits grades to 5 percent

41、of a design speed of 70 mph. For a design speed of 30 mph, maximum grades typically range from 7to 12 percent, depending on topography. Wherever long sustained grades are used, the designer should not substantially exceed the critical length of grade without the provision of climbing lanes for slow-

42、moving vehicles. Critical grade lengths vary from 1700 ft for a 3 percent grade to 500 ft for an 8 percent grade. Long sustained grades should be less than the maximum grade used on any particular section of a highway. It is of preferred to break the long sustained uniform grade by placing steeper g

43、rades at the bottom and lightening the gr4ade near the top of the ascent. Dips in the profile grade in which vehicles may be hidden from view should also be avoided. Maximum grade for highway is 9 percent. Standards setting minimum grades are of importance only when surface drainage is a problem as

44、when water must be carried away in a gutter or roadside ditch. In such instances the AASHTO suggests a minimum of 0.35%. C. Sight Distance For safe vehicle operation, highway must be designed to give drivers a sufficient distance of clear vision ahead so that they can avoid unexpected obstacles and

45、can pass slower vehicles without danger. Sight distance is the length of highway visible ahead to the driver of a vehicle. The concept of safe sight distance has two facts: “stopping” (or “nonpassing”) and “passing”. At times large objects may drop onto a roadway and will do serious damage to a moto

46、r vehicle that strikes them. Again a car or truck may be forced to stop in the traffic lane in the path of following vehicles. In either instance, proper design requires that such hazards become visible at distances great enough that drivers can stop before hitting them. Furthermore, it is unsafe to

47、 assume that one oncoming vehicle may avoid trouble by leaving the lane in which it is traveling, for this might result in loss of control or collision with another vehicle. Stopping sight distance is made up of two elements. The first is the distance traveled after the obstruction comes into view b

48、ut before the driver applies his brakes. During this period of perception and reaction, the vehicle travels at its initial velocity. The second distance is consumed while the driver brakes the vehicle to a stop. The first of these two distances is dependent on the speed of the vehicle and the perception time and brake-reaction time of the operator. The second distance depends on the speed of the vehicle; the condition of brakes, tire, and roadway surface; and the alig

展开阅读全文
相关资源
相关搜索

当前位置:首页 > 应用文书 > 策划方案

本站为文档C TO C交易模式,本站只提供存储空间、用户上传的文档直接被用户下载,本站只是中间服务平台,本站所有文档下载所得的收益归上传人(含作者)所有。本站仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。若文档所含内容侵犯了您的版权或隐私,请立即通知淘文阁网,我们立即给予删除!客服QQ:136780468 微信:18945177775 电话:18904686070

工信部备案号:黑ICP备15003705号© 2020-2023 www.taowenge.com 淘文阁