道路工程毕业设计外文翻译---高速公路设计与施工.docx
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1、道路工程毕业设计外文翻译-高速公路设计与施工 原文 Highway Design and Construction: The Innovation Challenge Author: Robert E. Skinner Jr. Innovations and advances in research are changing the way highways are built in America. The Egyptians were pouring concrete in 2500 BC, and the Romans used it to construct the Pantheon
2、and the Colosseum. By the mid-1800s, Europeans were building bridges with concrete, and the first “modern” concrete highway pavements appeared in the latter part of the 19th century. Naturally occurring asphalts, which have been used for waterproofing for thousands of years, came into common use in
3、road construction in the 1800s. The first iron bridge was constructed in 1774, but by the end of the 19th century steel had largely replaced iron in bridge construction. These materialsconcrete, asphalt, and steelare now the mainstays of highway and bridge construction throughout the world, as well
4、as of most types of public works infrastructure. Concrete and steel, the most versatile of these materials, are used for bridges and other highway structures; concrete and asphalt are used for roadway pavements. Everyone is familiar with concrete, asphalt, and steel, and some of us have worked with
5、them, perhaps on home improvement projects. This familiarity, coupled with the long history of their many uses, has led many otherwise technically savvy people to believe that these materials are well understood, that their performance can be easily and reliably predicted, and that the technical cha
6、llenges in using them for highways were overcome long ago. However, such notions are largely incorrect and misleading. For example, consider concrete, which is a mixture of portland cement, sand, aggregate (gravel or crushed stone), and water. Its performance characteristics are determined by the pr
7、oportions and characteristics of the components, as well as by how it is mixed and formed. The underlying chemical reactions of concrete are surprisingly complex, not completely understood, and vary with the type of stone. Steel may be added for tensile strength (reinforced concrete), and a variety
8、of additives have been identified to improve the workability and performance of concrete in particular applications and conditions. Damage and deterioration to concrete can result from excessive loadings and environmental conditions, such as freeze-thaw cycles and chemical reactions with salts used
9、for deicing. _ Many factors contribute to the urgent need for innovation in highway construction. _ Concrete is the most heavily used substance in the world after water (Sedgwick, 1991). Worldwide, concrete construction annually consumes about 1.6 billion tons of cement, 10 billion tons of sand and
10、crushed stone, and 1 billion tons of water (M.S. Kahn, 2022). Given transportation costs, there is a huge financial incentive to using local sources of stone, even if the properties of that stone are less than ideal. Thus concrete is not a homogenous material. In truth, an unlimited number of combin
11、ations and permutations are possible. Much the same can be said of asphalttechnically, asphaltic concretewhich is also a mixture of aggregate (gravel or crushed stone), sand, and cement (asphalt binder); economics promote the use of locally available materials; and the underlying chemistry is not we
12、ll understood. The characteristics of asphalt binder, for instance, vary depending on the source of crude oil from which it is derived. The metallurgy of steel is probably better understood than the chemistry of either asphalt or concrete, but it too is a mixture with virtually limitless combination
13、s. Strength, toughness, corrosion resistance, and weldability are some of the performance characteristics that vary with the type of steel alloy used and the intended applications. As uses evolve and economic conditions change, we have a continuing need for a more sophisticated understanding of thes
14、e common materials. Even though they are “mature” products, there is still room for significant incremental improvements in their performance. Because fundamental knowledge is still wanting, there is also considerable potential for breakthroughs in their performance. Factors That Affect Highway Cons
15、truction All other things being equal, stronger, longer lasting, less costly highway materials are desirable and, given the quantities involved, there are plenty of incentives for innovation. In highway transportation, however, all other things are not equal. A number of other factors contribute to
16、the urgent and continuing need for innovation. First, traffic volume and loadings continue to increase. Every day the U.S. highway network carries more traffic, including heavy trucks that were unimagined when the system was originally conceived and constructed. The 47,000-mile interstate highway sy
17、stem today carries more traffic than the entire U.S. highway system carried in 1956 when the interstates were laid out. The U.S. Department of Transportation (DOT) estimates that in metropolitan areas the annual cost of traffic congestion for businesses and citizens is nearly $170 billion (PB Consul
18、t, Inc., 2022). On rural interstates, overall traffic more than doubled between 1970 and 2022; at the same time, the loadings on those highways increased six-fold, mainly due to the increase in the number of trucks and the number of miles they travel. (Truck traffic increased from about 5.7 percent
19、of all vehicle-miles traveled on U.S. highways in 1965 to 7.5 percent in 2000 FHWA, 2022). Second, traffic disruptions must be kept to a minimum during construction. Our overstressed highway system is not very resilient. Thus disruptions of any sort, such as lane and roadway closings, especially in
20、major metropolitan areas and on key Interstate routes, can cause massive traffic snarls. This means that repair and reconstruction operations must often be done at night, which introduces a variety of additional complexities and safety issues. Occasionally, heroic measures must be taken to keep traf
21、fic moving during construction. For example, during construction of the “Big Dig” in Boston, the elevated Central Artery was in continuous service while cut-cover tunnels were constructed directly below it. Third, environmental, community, and safety requirements have become more stringent. For many
22、 good reasons, expectations of what a highway should be, how it should operate, and how it should interact with the environment and adjacent communities are constantly evolving. Designs to promote safety, measures to mitigate a growing list of environmental impacts, and attention to aesthetics have
23、fundamentally changed the scope of major highway projects in the United States. For example, on Marylands $2.4 billion Intercounty Connector project in suburban Washington, D.C., which is now under construction, environmental mitigation accounts for 15 percent of project costs, or about $15 million
24、per mile (AASHTO, 2022). Fourth, costs continue to rise. Building and maintaining highways cost effectively is an ever-present goal of good engineering. But cost increases in highway construction have been extraordinary due in part to the expanded scope of highway projects and construction in demand
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