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水利水电工程毕业设计英文翻译,混凝土重力坝

水利水电工程毕业设计英文翻译,混凝土重力坝

Concrete Gravity DamThe type of dam selected for a site depends principally on topographic, geologic,hydrologic, and climatic conditions. Where more than one type can be built, alternative economic estimates are prepared and selection is based on economica considerations.Safety and performance are primary requirements, but construction time and materials often affect economic comparisons.Dam ClassificationDams are classified according to construction materials such as concrete or earth. Concrete dams are further classified as gravity, arch, buttress, or a combination of these. Earthfill dams are gravity dams built of either earth or rock materials, with particular provisions for spillways and seepage control.A concrete gravity dam depends on its own weight for structural stability. The dam may be straight or slightly curved, with the water load transmitted through the dam to the foundation material. Ordinarily, gravity dams have a base width of 0.7 to 0.9 the height of the dam. Solid rock provides the best foundation condition. However, many small concrete dams are built on previous or soft foundations and perform satisfactorily. A concrete gravity dam is well suited for use with an overflow spillway crest. Because of this advantage, it is often combined with an earthfill dam in wide flood plain sites.Arch dams are well suited to narrow V- or U-shaped canyons. Canyon walls must be of rock suitable for carrying the transmitted water load to the sides of the canyon by arch action. Arch sections carry the greatest part of the load; vertical elements carry sufficient load through cantilever action to produce cantilever deflections equal to arch deflections. Ordinarily, the crest length-to-height ratio should be less than 5, although greater ratios have been used. Generally, the base width of modern arch dams is 0.1 to 0.3 the height of the impounded water. A spillway may be designed into the crest of an arch dam.Multiple arches similarly transmit loads to the abutment or ends of the arch. This type of dam is suited to wider valleys. The main thrust and radial shears are transmitted to massive buttresses and then into the foundation material.Buttress dams include flat-slab, multiple-arch, roundhead-buttress, and multiple-dome types. The buttress dam adapts to all site locations. Downstream face slabs and aprons are used for overflow spillways similar to gravity dam spillways. Inclined sliding gates or light-weight low-head gates control the flow.The water loads are transmitted to the foundation by two systems of load-carrying members. The flat slabs, arches, or domes support the direct water load. The face slabs are supported by vertical buttresses. In most flat-slab buttress dams, steel reinforcement is used to carry thetension forces developed in the face slabs and buttress supports. Massive-head buttresses eliminate most tension forces and steel is not necessary.Combiantion designs may utilize one or more of the previously mentioned types of dams. For example, studies may indicate that an earthfill dam with a center concrete gravity overflow spillway section is the most economial in a wide, flat valley. Other design conditions may dictate a multiple-arch and buttress dam section or a buttress and gravity dam combination.Site ExplorationThe dam location is determined by the project’s functions. The exact site within the general location must be determined by careful project consideration and systematic studies.In preliminary studies, two primary factors must be determined-the topography at the site and characteristics of the foundation materials. The first choice of the type of dam is based primarily on these two factors. However, the final choice will usually be controlled by construction cost if other site factors are also considered.Asite exploration requires the preparation of an accurate topographic map for each possible site in the general location. The scale of the maps should be large enough for layout. Exploration primarily determines the conditions that make sites usable or unusable.From the site explorations, tentative sketches can be made of the dam location and project features such as power plants. Physical features at the site must be ascertained in order to make a sketch of the dam and determine the position of materials and work plant during construction. Other factors that may affect dam selection are roadways,fishways, locks, and log passages.TopographyTopography often determines the type of dam. For example, a narrow V-shaped channel may dictate an arch dam. The topography indicates surface characteristics of the valley and the relation of the contours to the various requirements of the structure. Soundness of the rock surface must be included in the topographic study.In a location study, one should select the best position for the dam. An accurate sketch of the dam and how it fits into the topographic features of the valley are often sufficient to permit initial cost estimates. The tentative location of the other dam features should be included in this sketch since items such as spillways can influence the type and location of the dam.Topographic maps can be made from aerial surveys and subsequent contour plotting or they can be obtained from governmental agencies. The topographic survey should be correlated with the site exploration to ensure accuracy. Topographic maps give only the surface profile at thesite. Further geological and foundation analyses are necessary for a final determination of dam feasibility.Foundation and Geological InvestigationFoundation and geological conditions determine the factors that support the weight of the dam. The foundation materials limit the type of dam to a great extent, although such limitations can be compensated for in design.Initial exploration may consist of a few core holes drilled along the tentatively selected site location. Their analysis in relation to the general geology of the area often rules out certain sites as unfeasible, particularly as dam height increases. Once the number of possible site locations has been narrowed down, more detailed geological investiagtions should be considered.The location of all faults, contacts, zones of permeability, fissures, and other underground conditions must be accurately defined. The probable required excavation depth at all points should be derived from the core drill analysis. Extensive drilling into rock formations isn’t necessary for small dams. However, as dam height and safety requirements increase, investigations should be increased in depth and number. If foundation materials are soft, extensive investigations should determine their depth,permeability, and bearing capacity. It is not always necessary orpossible to put a concrete dam on solid rock.The different foundations commonly encountered for dam construction are: (1)solid rock foundations, (2) gravel foundations, (3) silt or fine sand foundations, (4) clay foundations, and (5) nonuniform foundation materials. Small dams on soft foundation ( item 2 through item 5 ) present some additonal design problems such as settlement, prevention of piping, excessive percolation, and protection of foundation from downstream toe erosion. These conditions are above the normal design forces of a concrete dam on a rock foundation. The same problems also exist for earth dams.Geological formations can often be pictured in cross-section by a qualified geologist if he has certain core drill holes upon which to base his overall concept of the geology. However, the plans and specifications should not contain this overall geological concept. Only the logs of the core drill holes should be included for the contractor’s estimates. However, the geological picture of the underlying formations is a great aid in evaluating the dam safety. The appendix consists of excerpts from a geologic report for the site used in the design examples.HydrologyHydrology studies are necessary to estimate diversion requirements during construction, to establish frequency of use of emergency spillways in conjunction with outlets or spillways, to determine peak dischargeestimates for diversion dams, and to provide the basis for power generation. Hydrologic studies are complex; however, simplified procedures may be used for small dams if certain conservative estimates are made to ensure structural safety.Formulas are only a guide to preliminary plans and design computations. The empirical equations provide only peak discharge estimates. However, the designer is more interested in the runoff volume associated with discharge and the time distribution of the flow. With these data, the designer knows both the peak discharge and the total inflow into the reservoir area. This provides a basis for making reliable diversion estimates for irrigation projects, water supply, or power generation.A reliable study of hydrology enables the designer to select the proper spillway capacity to ensure safety. The importance of a safe spillway cannot be overemphasized. Insufficient spillways have caused failures of dams. Adequate spillway capacity is of paramount importance for earthfill and rockfill dams. Concrete dams may be able to withstand moderate overtopping.Spillways release excess water that cannot be retained in the storage space of the reservoir. In the preliminary site exploration, the designer must consider spillway size and location. Site conditions greatly influence the selection of location, type, and components of a spillway. The design flows that the spillway must carry without endangering the dam areequally important. Therefore, study of streamflow is just as critical as the foundation and geological studies of the site.附录2外文翻译混凝土重力坝一个坝址的坝型选择,主要取决于地形、地质、水文和气候条件。

毕业设计毕业论文水电站文献翻译中国水利发电的现状和前景中英文对照

毕业设计毕业论文水电站文献翻译中国水利发电的现状和前景中英文对照

外文资料China's hydroelectric power the current situation and prospectsAbstract: The electricity is a modern industrial production and the life of an essential driving force for energy, hydroelectric power industry is a category. The founding of the past 50 years, China's hydropower industry has developed by leaps and bounds, has made remarkable achievements. The rise of hydropower in China there is a profound background.Key words: Hydro-electric power Status ProspectsFirst, China has a large-scale utilization of water resources and the need for the conditions. China's abundant hydropower resources, whether they are reserves of hydropower resources, or the possible development of hydropower resources in the countries in the world in the first rank. But China's energy utilization rate is only 13 percent, hydropower prospects are bright. As China's rapid economic growth, total energy consumption is also up sharply, coal, oil and gas these conventional energy consumption growing, or even need to rely on imports. It is estimated that by 2010 China's need to import about 100 million t of oil, and its dependence on imports will reach 40 percent or even higher. In such a situation, the development of new energy was particularly important and urgent. The water is a renewable and new energy, an inexhaustible supply of it.Second, the development of hydropower is also the need for environmental protection. Conventional power generation, coal combustion emissions in the course of a large number of hazardous substances so that the atmospheric environment is seriously contaminated, and acid rain caused "greenhouse effect", and many other environmental problems. And nuclear power generation have great potential risk, once the pollution caused by leakage, damage to the environment is immeasurable role. Hydro-electric power is not emissions of harmful gases,dust and ash, and no nuclear radiation pollution, is a clean power production, has obvious advantages.Third, hydro-electric power after more than a century of development, construction technology, manufacturing technology and hydro-generator groups in the transmission technology improved, stand-alone capacity has been increased. And low-cost hydro-electric power, running the high reliability, the extremely rapid development.1 Overview of China's hydropower resourcesChina's many rivers, rich runoff, huge gap, contains abundant hydropower resources. According to statistics, China's river water resources reserves 676 million kw, the generating capacity of 592.2 billion kwh; possible development of hydropower resources of the installed capacity of 378 million kw, the generating capacity of 920 billion kwh.Due to climate and topographical factors such as topography of the impact of China's hydropower resources in different regions and different distribution is very uneven Basin; China's hydropower resources of the river is a prominent characteristic of the steep river, the huge gap, originated the "roof of the world" Qinghai-Tibet Plateau of the Yangtze River, Yellow River and Yarlung Zangbo River, Lancang River, Nujiang River, the natural differences are about as high as 5000 m, forming a series of the world's largest rivers divide, which is not found in other countries. Full understanding of the characteristics of China's hydropower resources can be in the development process in light of local conditions, reasonably full use of hydropower resources.2 status quo of China's hydropower developmentA century, particularly since 1949, after several generations of hydropower builders of hard work, China's hydropower construction from small to large and from weak to strong continue to grow and develop. Since reform and opening up, utilities are building more rapid development of projects have been expanding. 1950s to the early 1960s, mainly repairing the dam and power station fullness, Dragon River. Gutian, and other minor works, initiated the development of small and medium hydropower (such as 114-8508, the Huaihe River, Huangtankou, Liuxihe, such as power stations). In the late 1950s in terms gradually mature, a number of rivers cascade development, such as Shizitan, salt Yanguoxia, Tuo River,Xinfengjiang, Xin'anjiang, the West-and cat jumping into a river to river at the works. The mid-1960s to the late 1970s during the period has started Gongzui, Yingxiuwan, Wujiangdu, Bikou, Fung Beach, Longyangxia, Baishan, Dahua and other projects. The early 1970s first 1000 MW installed capacity of the Liujiaxia Hydropower Station production. 2715 MW capacity of the 1980s the completion of the Gezhouba Hydropower Station, after a series of big hydropower stations have been building, 18200 MW capacity of the Three Gorges Project has started in 1994 and by the end of 2000, the 1000 MW larger than the largest hydropower station (not including Storage Power Station) has 18.In addition to conventional hydropower station, China's pumped-storage power station building has made great achievements. Pumped Storage Power Station was built in the main hydraulic fewer resources, to meet the needs of the power system peak load regulation. The construction of the main Pumped Storage Power Station are as follows:Guangzhou Pumped Storage Power Station to the total capacity of 2.4 million kw, is the first Block is currently the world's largest pumped-storage power station. Power station construction in two phases with a total capacity of eight, each lasting four and a capacity of 300,000 kw reversible high parameters of pumped storage units, the design of head 535 m, rated speed 500 r / min, comprehensive efficiency of 76 percent.Jiang Tianhuangping Pumped Storage Power Station, a total installed capacity of 1.8 million kw, a regulation on pure pumped storage power station, power consumption, pumping 4.28 billion kwh. North China Power Grid's largest pumped-storage power plant Ming Tombs Pumped Storage Power Station, "the Ming Tombs Reservoir" for the next pool, using plastic concrete cutoff wall hanging seepage control technology, power plants to install four 200,000 kw Francis River inverse-turbine pumps, an electric generating units, the installed capacity of 800,000 kw.Hebei Panjiakou hybrid pumped-storage power station, equipped with a conventional Taiwan 150,000 kw hydro-generator group, there are three pumped-storage units, each of 90,000 kw, total installed capacity of 420,000 kw.In addition, China's construction in Tibet also has the world's highest Pumped Storage Power Station Yangzhuoyong Lake pumped-storage power station. Pumped Storage PowerStation is also available in other Baoquan pumped storage power plant in Henan, Anhui Langyashan Pumped Storage Power Station, Shandong Taian Pumped Storage Power Station, Tongbai Pumped Storage Power Station in Zhejiang, Yixing in Jiangsu Pumped Storage Power Station, Hebei Zhang Nihewan Pumped Storage Power Station.3 China's hydropower development problems facing theChina's hydropower industry in nation-building after a considerable development, but there are still many problems. For example, the Ertan Hydropower Station in Sichuan Province since 1949 is the most intensive investment, the largest engineering, technical difficulty of the highest building projects, but an operation on the face of the enormous waste of resources and enterprises to huge losses this embarrassing position. The situation prevailing in China's hydropower station. The reasons were mainly the following points.First, the management system, a high degree of monopoly power industry system hindered the development of hydropower. China's Ministry of Water Resources and Ministry of Water and Power and management, and water conservancy and hydroelectric power is the power of the integrated projects, but the Ministry and its subordinate electric power throughout the production and scheduling system none of the staff from thermal power systems, power industry from nature Or that a high degree of monopoly industries, enterprises full control of a single power scheduling, power distribution, electricity sales, electricity billing and other powers. At the same time the electricity market in the period of relative surplus of hydroelectric power, thermal power contradiction between the very sharp and in China under the present circumstances, the priority use of hydropower resources can not be guaranteed, a large number of hydropower resources have been wasted. Hydropower and the Internet generally low tariffs, we can imagine the state of hydropower stations. Opening up the electricity market, breaking the monopoly of the power industry system, water and electricity problem is to solve the fundamental way. At the same time, the Internet tariff for water and electricity reform, "debt service tariff" that electricity tariff structure to a single bi-use electricity price of the electricity tariff structure.Secondly, in the current economic interests, the number of thermal power production, with the size of the economic benefits are directly related to mine. China's long-term mainly to thermal power, thermal power plants with their long-established fixed in a coal mine, if weuse water and electricity to replace thermal power, thermal power plants will face not only the pressure, coal will face great pressure, resulting in thermal power plants and coal mines Two aspects of the economic difficulties. Therefore, departments or units by the economic interests of the drive to form a "protective thermal power and hydropower light" situation, and this caused a lot of hydropower resources have been wasted, and even disposable loss of electricity consumption significantly higher than the actual Internet.Third, technically, since the peak shaving or water and electricity load rejection is relatively easy, even a few minutes to complete the start-up of large hydropower generating units and electricity networks, or stopping, and at the same level of capacity thermal power unit may need a few 10 hours to complete the start or stop. Therefore, in the scheduling grid, the hydropower generating units are often used to peak shaving or backup units, in sufficient water to flood when the power generation, but its importance in the era of conventional power generation applications, resulting in the huge waste of water and electricity.In short, the cause of China's water and electricity problems faced by people in the final analysis is ideologically not aware of the need for the development of hydropower and urgency of water and electricity often because there are one-time investment objective, long construction period, less completed early return The characteristics, and only on the immediate economic interests, water and electricity to the development of multiple objective of the resistance. Therefore, we should vigorously promote the development of hydropower in China is by the great significance of changing the concept of water and electricity, essentially wiping out all kinds of obstacles.4 China's hydropower development prospectsWith the deepening of reform and national economic development, China's electricity market situation has undergone fundamental changes from the previous power and capacity of the "double vacancy" into a relative surplus of electricity and peak shaving a serious shortage of capacity, to the development of hydropower A good opportunity.4.l general principleNow and in the future some time, China's hydropower development should be the main priority and good regulation of hydropower stations and power industry from all socio-economic development point of view and consider comprehensive study on hydropower development and strength and to prevent waste; reasonable evaluation Pumped Storage Utility economic benefits, fully aware of the pumped-storage power station filled valley, peak shaving, FM, PM, incidents such as back-up role in the importance of coordinated development in the eastern part of the pumped-storage power station; further strengthen water and electricity "basins, Cascade, and rolling, comprehensive "way of development; pay more attention to ecological problems.4.2 ladder to development and construction of hydropower baseChina's hydropower resources are mainly located in the western region, accounting for more than three quarters, but the current development rate of eight percent. Especially Yunnan Province, the province's total installed hydropower capacity can be developed about 90 million kw, the country's total installed capacity of hydropower development can be 23.8 percent, ranking the second in the provincial water resources are mainly located in the Jinsha River, Lancang River, Nujiang River, Pearl River, Red River and the Irrawaddy, such as Jiang's six major river systems, in western China is the most potential for hydropower development of the main provinces. However, Yunnan Province's industrial base is relatively backward, electricity and water resources are mainly located in the inconvenience of cross mountains, the development more difficult. With the great western development strategy for the implementation of the West, East project will lose the activation of the rich hydropower resources, and promote the cause of China's hydropower development. Yunnan Province to play the regional advantages, to build China's hydropower energy base, and the West, East lose, both local economic development to meet the demand for electricity, but also optimize the country's energy structure.At present, Chuan Xinan than the total installed capacity of the Three Gorges Power Station is also a 600,000 kw of the Xiluodu and Xiangjiaba hydropower station two giant project formally approved by the State Council, which will be China's largest hydropower base. Luobo River Power Station in Leibo County in Sichuan Province and Yongshan County in Yunnan Province at the junction of the design capacity of 12.6 million kw, the average annual generating capacity of 57.12 billion kwh; Xiangjiaba Hydropower Station located in Yibin County, Sichuan Province and Yunnan Province Fuxian water at the junction, thecapacity of 6 million kw, the average annual generating capacity of 30.7 billion kwh. That the construction of two power stations with a strong ability to adjust, less farmland inundated, immigration and other less one of the advantages of large-scale hydropower stations. The two giant hydropower station project marks the official start of China's large-scale development of hydropower resources of the upper reaches of the Yangtze River, the upper reaches of the Yangtze River hydropower resources development will greatly improve China's power structure, lay the West, the East lost the general pattern of nationwide The energy balance and optimize the allocation.4.3 continue to attach importance to the development of small hydropowerChina's small hydropower resources are very rich reserves of around 150 million kw, to develop capacity is about more than 70 million kw, in the corresponding generation of about 200 billion - 250 billion kwh. Small Hydropower in addition to large-sized hydropower is not the atmospheric pollution, the use of renewable energy without the worry of energy depletion, low-cost advantages of its resources, He scattered on the negative impact on the ecological environment, the technology is mature, less investment, easy to build, Therefore suitable for the rural and mountainous areas, especially rural and mountainous areas in developing countries.China, as developing countries, small hydropower construction has made great achievements, to the end of 1997, China's total installed capacity of small hydropower has reached 20.52 million kw, the generating capacity of 68.3 billion kwh. Small hydropower construction in most cases can be the local building materials to absorb the local labor force building, thereby reducing construction costs, and easier to standardize their equipment, can reduce the cost and shorten the construction period, no complicated expensive technology is conducive to China's economic underdevelopment in the mountains and Achieving rural electrification, which should continue to attach importance to its development and construction.中国水利发电的现状和前景摘要:电力是现代化工业生产和生活不可或缺的动力能量,水力发电是电力工业的一个门类。

水利水电毕业设计外文文献翻译

水利水电毕业设计外文文献翻译

水工建筑物,29卷,9号,1995旋涡隧道溢洪道。

液压操作条件M . A .戈蓝,B. zhivotovskii,我·诺维科娃,V . B .罗季奥诺夫,和NN罗萨娜娃隧道式溢洪道,广泛应用于中、高压液压工程。

因此研究这类溢洪道这是一个重要的和紧迫的任务,帮助在水工建筑中使用这些类型的溢洪道可以帮助制定最佳的和可靠的溢洪道结构。

有鉴于此,我们希望引起读者的注意,基本上是新的概念(即,在配置和操作条件),利用旋涡流溢洪道[1,2,3,4 ]。

一方面,这些类型的溢洪道可能大规模的耗散的动能的流动的尾段。

因此,流量稍涡旋式和轴向流经溢洪道的尾端,不会产生汽蚀损害。

另一方面,在危险的影响下,高流量的流线型面下降超过长度时,最初的尾水管增加的压力在墙上所造成的离心力的影响。

一些结构性的研究隧道溢洪道液压等工程rogunskii,泰瑞,tel'mamskii,和tupolangskii液压工程的基础上存在的不同的经营原则现在已经完成了。

这些结构可能是分为以下基本组:-涡旋式(或所谓的single-vortex型)与光滑溢洪道水流的消能在隧道的长度时的研究的直径和高度的隧道;参看。

图1),而横截面的隧道是圆或近圆其整个长度。

涡旋式溢洪道-与越来越大的能量耗散的旋涡流在较短的长度- <(60——80)高温非圆断面导流洞(马蹄形,方形,三角形),连接到涡室或通过一个耗能(扩大)室(图2)[ 5,6 ]或手段顺利过渡断[ 7];-溢洪道两根或更多互动旋涡流动耗能放电室[ 8 ]或特殊耗能器,被称为“counter-vortex耗能”[ 2,4 ]。

终端部分尾水洞涡流溢洪道可以构造的形式,一个挑斗,消力池,或特殊结构取决于流量的出口从隧道和条件的下游航道。

液压系统用于的流量的尾管可能涉及可以使用overflowtype或自由落体式结构。

涡旋式溢洪道光滑或加速[ 7 ]能量耗散的整个长度的水管道是最简单和最有前途的各类液压结构。

水利类英文文献译文

水利类英文文献译文

Hand Move Irrigation SystemsSummaryThe ‘hand move’ irrigation system is a very simple pipe set which can be moved by hand. Two main factors-—positioning and moving scheme of the equipment both affect the work time. Here we develop a model to complete the irrigation of the whole field by the shortest time。

Firstly, we decide the certain number of sprinklers through the designated parameter。

Using enumerative geometry, we compare the irrigation area of the system with different number of sprinklers and work out the optimum number of sprinklers。

Secondly, we take the advantage of combinatorial geometry to decide the positioning and moving scheme of the irrigation system,in order that the model can be used to realize the irrigation task by the shortest work time.In the end we also introduce a new sprinkler with square area and compare its working efficiency with the traditional sprinkler if we use it on this field。

毕业设计水利水电工程英文文献翻译

毕业设计水利水电工程英文文献翻译

毕业设计水利水电工程英文文献翻译外文文献:hydraulicturbines and hydro-electric powerAbstractPower may be developed from water by three fundamental processes : by action of its weight, of its pressure, or of its velocity, or by a combination of any or all three. In modern practice the Pelton or impulse wheel is the only type which obtains power by a single process the action of one or more high-velocity jets. This type of wheel is usually found in high-head developments. Faraday had shown that when a coil is rotated in a magnetic field electricity is generated. Thus, in order to produce electrical energy, it is necessary that we should produce mechanical energy, which can be used to rotate the ‘coil’. The mechanical energy is produced by running a prime mover (known as turbine ) by the energy of fuels or flowing water. This mechanical power is converted into electrical power by electric generator which is directly coupled to the shaft of turbine and is thus run by turbine. The electrical power, which is consequently obtained at the terminals of thegenerator, is then transited to the area where it is to be used for doing work.he plant or machinery which is required to produce electricity (i.e. prime mover +electric generator) is collectively known as power plant. The building, in which the entire machinery along with other auxiliary units is installed, is known as power house.Keywords hydraulic turbines hydro-electric power classification of hydel plantshead schemeThere has been practically no increase in the efficiency of hydraulic turbines since about 1925, when maximum efficiencies reached 93% or more. As far as maximum efficiency is concerned, the hydraulic turbine has about reached the practicable limit of development. Nevertheless, in recent years, there has been a rapid and marked increase in the physical size and horsepower capacity of individual units.In addition, there has been considerable research into the cause and prevention of cavitation, which allows the advantages of higher specific speeds to be obtainedat higher heads than formerly were considered advisable. The net effect of this progress with larger units, higher specific speed, and simplification and improvements in design has been to retain for the hydraulic turbine the important place which it has long held at one of the most important prime movers.1. types of hydraulic turbinesHydraulic turbines may be grouped in two general classes: the impulse type which utilizes the kinetic energy of a high-velocity jet which acts upon only a small part of the circumference at any instant, and the reaction type which develops power from the combined action of pressure and velocity of the water that completely fills the runner and water passages. The reaction group is divided into two general types: the Francis, sometimes called the reaction type, and the propeller type. The propeller class is also further subdivided into the fixed-blade propeller type, and the adjustable-blade type of which the Kaplan is representative.1.1 impulse wheelsWith the impulse wheel the potential energy of thewater in the penstock is transformed into kinetic energy in a jet issuing from the orifice of a nozzle. This jet discharge freely into the atmosphere inside the wheel housing and strikes against the bowl-shaped buckets of the runner. At each revolution the bucket enters, passes through, and passes out of the jet, during which time it receives the full impact force of the jet. This produces a rapid hammer blow upon the bucket. At the same time the bucket is subjected to the centrifugal force tending to separate the bucket from its disk. On account of the stresses so produced and also the scouring effects of the water flowing over the working surface of the bowl, material of high quality of resistance against hydraulic wear and fatigue is required. Only for very low heads can cast iron be employed. Bronze and annealed cast steel are normally used.1.2 Francis runnersWith the Francis type the water enters from a casing or flume with a relatively low velocity, passes through guide vanes or gates located around the circumstance, and flows through the runner, from which it discharges into a draft tube sealed below the tail-water level. All therunner passages are completely filled with water, which acts upon the whole circumference of the runner. Only a portion of the power is derived from the dynamic action due to the velocity of the water, a large part of the power being obtained from the difference in pressure acting on the front and back of the runner buckets. The draft tube allows maximum utilization of the available head, both because of the suction created below the runner by the vertical column of water and because the outlet of he draft tube is larger than the throat just below the runner, thus utilizing a part of the kinetic energy of the water leaving the runner blades.1.3 propeller runnersnherently suitable for low-head developments, the propeller-type unit has effected marked economics within the range of head to which it is adapted. The higher speed of this type of turbine results in a lower-cost generator and somewhat smaller powerhouse substructure and superstructure. Propeller-type runners for low heads and small outputs are sometimes constructed of cast iron. For heads above 20 ft, they are made of cast steel, a much more reliable material. Large-diameter propellers。

毕业设计论文-水利工程外文翻译—水利水电工程施工的布置方案设计

毕业设计论文-水利工程外文翻译—水利水电工程施工的布置方案设计

英文原文:Water Resources and Hydropower Engineering ConstructionDesign Layout[Key words] construction layout Fuzzy multiple attribute decisionmaking Water Resources and Hydropower Construction[Abstract] Analysis of affecting factors of the construction layout program characteristics that people value in identifying these indicators fuzzy constraints are difficult to give exact values, while decision-making process has been one of psychological, subjective will and the work experience and other aspects influence decision-making process and therefore there is certainly ambiguity.1, Water Resources and Hydropower Engineering Construction Layout FactorsConstruction advantages and disadvantages of the general layout scheme, involving many factors, from different angles to evaluate the evaluation factors generally have two categories, qualitative factors, and quantitative factors of a class. Qualitative factors are mainly: 1. Favorable production, easy to administer, facilitate the degree of life; 2. During the construction process, the degree of co-ordination; 3. The principal impact of construction and operation; 4. Meet the security, fire, flood prevention, environmental protection requirements; 5. Temporary Works and the combination of permanent works and so on. Indicators are mainly quantitative factors;1. Site preparation earthwork quantity and cost;2. The extent of use of earth excavation;3. Temporary works of construction work quantity and cost;4. Workload and a variety of materials, transport costs;5. Size and cost of land acquisition;6. Made to the area to field, the recovery or recycling construction fees.As the construction is construction planning layout content, is that people under work experience, combined with engineering data on the occurrence of a future prediction about. Therefore, both qualitative factors, and the quantitative factors, there is uncertainty. We know that the uncertainty of two different forms; one is uncertain whether the incident occurred in 11 random, the event itself the state of uncertainty 11 ambiguity. Randomness is an external cause in general uncertain, but ambiguity is an inherent uncertainty of the structure. From the information point of view, therandomness involves only the amount of information, while the ambiguity is related to the meaning of information. We can say that ambiguity is more profound than the randomness, the uncertainty more generally, especially in the subjective understanding of areas of role ambiguity is much more important than the role of randomness. Random people for a lot of research has been carried out, achieved fruitful results; while ambiguity was ongoing and in-depth knowledge and research in the. All people involved in the system, carried out by people planning, feasibility studies, evaluation of decision-making, design and management, and therefore, can not ignore the objective world of things in the human brain, one by one to reflect the uncertainty of ambiguity, it is an objective difference intermediate division caused by the transition of a kind of uncertainty. Construction Layout Design is no exception, in the arrangement of construction there are a large number of objective fuzzy factors. For example, the construction of facilities, coordination between the levels of "good" and "general" is an accurate value can not be described. Therefore, the arrangement can not ignore or avoid the construction of the fuzziness existing in the process, but should be objective and deal with ambiguity of this objective, understand the rules for people planning, demonstration, evaluation and decision, design and management to provide a scientific basis and methods.As the construction layout of the content involved in more programs fuzzy factors exist, the traditional construction arrangement he considered the existence of ambiguity, but in decision-making process has fuzzy information precision, not a real fuzzy optimization. Therefore, the program should focus on optimization of fuzzy factors into account, the ambiguity should be reflected in the decision-making on the index, index weights. For quantitative indicators, mainly the amount and cost of the project issues, its value can be found in engineering materials and design documents to determine by calculation, the results are the values of the parameters and experience. As every engineer's understanding of things is not the same experience in a certain range of parameter changes, the results also in a certain range. For qualitative indicators, according to experts, engineering experience, through expert scoring method, set the value of statistics to determine. Such subjective factors, the knowledge structure and decision-making preferences play a major role. But in practice, due to the complexity of objective things and the people's thinking on the use of fuzzy concept, to describe with precision the number becomes very difficult, but with "some", "left"and the like get fuzzy concept to describe the more reasonable. Determine the weights of evaluation indexes, there are many mathematical ways to determine the accurate calculation. We know, for different projects, in the same factors, their importance is not the same, then the mathematical model is difficult to fully reflect the actual situation, the help of experts in engineering experience must be judged.Since the existence of the above ambiguity, avoid or ignore the ambiguity is unscientific, incomplete. Previous index value that decision-making, decision weights for programs for determining the value of the preferred method, there is bound to sidedness and limitations. As technology develops, people are increasingly demanding of precision, the object of study become more complicated, as complicated to some degree after the meaning of the precise cognitive declines and the appropriate fuzzy but accurate. Here, the introduction of fuzzy mathematical tools, the use of modern fuzzy multiple attribute decision making theory, Fuzzy multiple attribute decision making model, can exist for people to consider the ambiguity of the objective, to provide strong support for rational decision-making.2, Water Resources and Hydropower Engineering Construction Design LayoutConstruction Layout as a focus of the system around the concrete layout of the temporary structures. There are 1. All kinds of storage, stockpile and Spoil; 2. Mechanical repair system; 3. Metal structure, mechanical and electrical equipment and construction equipment installed base; 4. Wind, water and electricity supply systems; 5. Other construction plant, such as steel processing, wood processing, prefabricated factory; 6. Office and living space, such as offices, laboratories, dormitories, hospitals, schools, etc.; 7. Fire safety facilities and other, such as fire stations, guard, and security cordon so. At this time, various types of temporary structures should be put forward, the construction of facilities furnished a list of partial pressure, their area, building area and volume of construction and installation; on fertilization with an estimate of land acquisition, land area and the proposed land use plan, the study to reclaiming land in the use of the measures, site preparation earthwork volume calculations, the integrated cut and fill balance of the proposed excavation of the use of effective planning.Construction of facilities in order to avoid conflict between the layouts, construction of facilities in the analysis of adjacency relations, is to analyze the relationship between the construction of facilities, strength of correlation andrelationship. Usually based on the adjacency relationship, consider the construction schedule, construction strength, facilities operation and logistics. Analysis of the size and layout of the construction of facilities present at the location of the ground between the site controlled the indicators are: 1. The scale of construction facilities layout, the main considerations to meet the construction requirements of the case, the construction of facilities, capacity and layout area. 2. Foundation bearing capacity of the construction of facilities to consider geology, slope stability and so on. 3. Hydrological requirements and construction guide closure of the case, consider the different construction periods, flood, water table, water level changes in the construction site layout planning of construction restrictions and impact. 4. The height difference logistics constraints, considering logistics and vertical elevation gradient lines, logistics of import and export. 5. Construction of the distance between these facilities and restrictions, mainly refers to the construction of facilities necessary for running the minimum operating radius, the minimum limit transportation question, minimum import and export logistics, construction and facilities, the safety distance between. 6. Construction site area of internal and external traffic conditions, construction equipment, consider the minimum safe height and width of the transport, building materials inside the transport requirements.To be concrete system facilities arranged in a prominent position, so that interference by the other facilities as small as possible, the need for construction of facilities at this time analysis of the relationship between the adjacent, as many facilities for Hydropower Construction, different facilities have a clear focus on functionality, such as depots, gas stations, etc., if not for the neighbor relations analysis, because the construction of facilities for the inter-functional conflict, construction and project management to bring incalculable damage and safety hazards buried.References:[1] Lu Yu Mei editor of the Three Gorges Dam Construction [M]. Beijing: China Electric Power Press, 2003[2] Wei-Jun Zhu, Zhang Xiaojun and so the overall layout design of the Three Gorges Project Construction [J]. The people of the Yangtze River, 2001.32 (10) :4-5.译文:水利水电工程施工的布置方案设计[关键词]施工布置模糊多属性决策水利水电施工[论文摘要]分析施工布置方案的影响因素特点,指出人们在确定这些指标值时受到模糊性因素的限制很难给出精确值,同时决策过程还受到人们心理、主观意愿和工作经验等多方面的影响,因而决策过程也必然存在模糊性。

毕业设计水利水电工程英文文献翻译

毕业设计水利水电工程英文文献翻译

外文文献:hydraulicturbines and hydro-electric powerAbstractPower may be developed from water by three fundamental processes : by action of its weight, of its pressure, or of its velocity, or by a combination of any or all three. In modern practice the Pelton or impulse wheel is the only type which obtains power by a single process the action of one or more high-velocity jets. This type of wheel is usually found in high-head developments. Faraday had shown that when a coil is rotated in a magnetic field electricity is generated. Thus, in order to produce electrical energy, it is necessary that we should produce mechanical energy, which can be used to rotate the …coil‟. The mechanical energy is produced by running a prime mover (known as turbine ) by the energy of fuels or flowing water. This mechanical power is converted into electrical power by electric generator which is directly coupled to the shaft of turbine and is thus run by turbine. The electrical power, which is consequently obtained at the terminals of the generator, is then transited to the area where it is to be used for doing work.he plant or machinery which is required to produce electricity (i.e. prime mover +electric generator) is collectively known as power plant. The building, in which the entire machinery along with other auxiliary units is installed, is known as power house.Keywords hydraulic turbines hydro-electric power classification of hydel plants head schemeThere has been practically no increase in the efficiency of hydraulic turbines since about 1925, when maximum efficiencies reached 93% or more. As far as maximum efficiency is concerned, the hydraulic turbine has about reached the practicable limit of development. Nevertheless, in recent years, there has been a rapid and marked increase in the physical size and horsepower capacity of individual units.In addition, there has been considerable research into the cause and prevention ofcavitation, which allows the advantages of higher specific speeds to be obtained at higher heads than formerly were considered advisable. The net effect of this progress with larger units, higher specific speed, and simplification and improvements in design has been to retain for the hydraulic turbine the important place which it has long held at one of the most important prime movers.1. types of hydraulic turbinesHydraulic turbines may be grouped in two general classes: the impulse type which utilizes the kinetic energy of a high-velocity jet which acts upon only a small part of the circumference at any instant, and the reaction type which develops power from the combined action of pressure and velocity of the water that completely fills the runner and water passages. The reaction group is divided into two general types: the Francis, sometimes called the reaction type, and the propeller type. The propeller class is also further subdivided into the fixed-blade propeller type, and the adjustable-blade type of which the Kaplan is representative.1.1 impulse wheelsWith the impulse wheel the potential energy of the water in the penstock is transformed into kinetic energy in a jet issuing from the orifice of a nozzle. This jet discharge freely into the atmosphere inside the wheel housing and strikes against the bowl-shaped buckets of the runner. At each revolution the bucket enters, passes through, and passes out of the jet, during which time it receives the full impact force of the jet. This produces a rapid hammer blow upon the bucket. At the same time the bucket is subjected to the centrifugal force tending to separate the bucket from its disk. On account of the stresses so produced and also the scouring effects of the water flowing over the working surface of the bowl, material of high quality of resistance against hydraulic wear and fatigue is required. Only for very low heads can cast iron be employed. Bronze and annealed cast steel are normally used.1.2 Francis runnersWith the Francis type the water enters from a casing or flume with a relatively low velocity, passes through guide vanes or gates located around the circumstance, and flows through the runner, from which it discharges into a draft tube sealed below the tail-water level. All the runner passages are completely filled with water, which acts upon the whole circumference of the runner. Only a portion of the power is derived from the dynamic action due to the velocity of the water, a large part of the power being obtained from the difference in pressure acting on the front and back of the runner buckets. The draft tube allows maximum utilization of the available head, both because of the suction created below the runner by the vertical column of water and because the outlet of he draft tube is larger than the throat just below the runner, thus utilizing a part of the kinetic energy of the water leaving the runner blades.1.3 propeller runnersnherently suitable for low-head developments, the propeller-type unit has effected marked economics within the range of head to which it is adapted. The higher speed of this type of turbine results in a lower-cost generator and somewhat smaller powerhouse substructure and superstructure. Propeller-type runners for low heads and small outputs are sometimes constructed of cast iron. For heads above 20 ft, they are made of cast steel, a much more reliable material. Large-diameter propellers may have individual blades fastened to the hub.1.4 adjustable-blade runnersThe adjustable-blade propeller type is a development from the fixed-blade propeller wheel. One of the best-known units of this type is the Kaplan unit, in which the blades may be rotated to the most efficient angle by a hydraulic servomotor. A cam on the governor is used to cause the blade angle to change with the gate position so that high efficiency is always obtained at almost any percentage of full load.By reason of its high efficiency at all gate openings, the adjustable-blade propeller-type unit is particularly applicable to low-head developments where conditions are such that the units must be operated at varying load and varying head. Capital cost and maintenance for such units are necessarily higher than for fixed-blade propeller-type units operated at the point of maximum efficiency.2. thermal and hydropowerAs stated earlier, the turbine blades can be made to run by the energy of fuels or flowing water. When fuel is used to produce steam for running the steam turbine, then the power generated is known as thermal power. The fuel which is to be used for generating steam may either be an ordinary fuel such as coal, fuel oil, etc., or atomic fuel or nuclear fuel. Coal is simply burnt to produce steam from water and is the simplest and oldest type of fuel. Diesel oil, etc. may also be used as fuels for producing steam. Atomic fuels such as uranium or thorium may also be used to produce steam. When conventional type of fuels such s coal, oil, etc. (called fossils ) is used to produce steam for running the turbines, the power house is generally called an Ordinary thermal power station or Thermal power station. But when atomic fuel is used to produce steam, the power station, which is essentially a thermal power station, is called an atomic power station or nuclear power station. In an ordinary thermal power station, steam is produced in a water boiler, while in the atomic power station; the boiler is replaced y a nuclear reactor and steam generator for raising steam. The electric power generated in both these cases is known as thermal power and the scheme is called thermal power scheme.But, when the energy of the flowing water is used to run the turbines, then the electricity generated is called hydroelectric power. This scheme is known as hydro scheme, and the power house is known as hydel power station or hydroelectric power station. In a hydro scheme, a certain quantity of water at a certain potential head isessentially made to flow through the turbines. The head causing flow runs the turbine blades, and thus producing electricity from the generator coupled to turbine. In this chapter, we are concerned with hydel scheme only.3.classification of hydel plantsHydro-plants may be classified on the basis of hydraulic characteristics as follow: ①run-off river plants .②storage plants.③pumped storage plants.④tidal plants. they are described below.(1)Run-off river plants.These plants are those which utilize the minimum flow in a river having no appreciable pondage on its upstream side. A weir or a barrage is sometimes constructed across a river simply to raise and maintain the water level at a pre-determined level within narrow limits of fluctuations, either solely for the power plants or for some other purpose where the power plant may be incidental. Such a scheme is essentially a low head scheme and may be suitable only on a perennial river having sufficient dry weather flow of such a magnitude as to make the development worthwhile.Run-off river plants generally have a very limited storage capacity, and can use water only when it comes. This small storage capacity is provided for meeting the hourly fluctuations of load. When the available discharge at site is more than the demand (during off-peak hours ) the excess water is temporarily stored in the pond on the upstream side of the barrage, which is then utilized during the peak hours.he various examples of run-off the river pant are: Ganguwal and Kolta power houses located on Nangal Hydel Channel, Mohammad Pur and Pathri power houses on Ganga Canal and Sarda power house on Sarda Canal.The various stations constructed on irrigation channels at the sites of falls, also fall under this category of plants.(2) Storage plantsA storage plant is essentially having an upstream storage reservoir of sufficient size so as to permit, sufficient carryover storage from the monsoon season to the dry summer season, and thus to develop a firm flow substantially more than minimum natural flow. In this scheme, a dam is constructed across the river and the power house may be located at the foot of the dam such as in Bhakra, Hirakud, Rihand projects etc. the power house may sometimes be located much away from the dam (on the downstream side). In such a case, the power house is located at the end of tunnels which carry water from the reservoir. The tunnels are connected to the power house machines by means of pressure pen-stocks which may either be underground (as in Mainthon and Koyna projects) or may be kept exposed (as in Kundah project).When the power house is located near the dam, as is generally done in the low head installations ; it is known as concentrated fall hydroelectric development. Butwhen the water is carried to the power house at a considerable distance from the dam through a canal, tunnel, or pen-stock; it is known as a divided fall development.(3) Pumped storage plants.A pumped storage plant generates power during peak hours, but during the off-peak hours, water is pumped back from the tail water pool to the headwater pool for future use. The pumps are run by some secondary power from some other plant in the system. The plant is thus primarily meant for assisting an existing thermal plant or some other hydel plant.During peak hours, the water flows from the reservoir to the turbine and electricity is generated. During off-peak hours, the excess power is available from some other plant, and is utilized for pumping water from the tail pool to the head pool, this minor plant thus supplements the power of another major plant. In such a scheme, the same water is utilized again and again and no water is wasted.For heads varying between 15m to 90m, reservoir pump turbines have been devised, which can function both as a turbine as well as a pump. Such reversible turbines can work at relatively high efficiencies and can help in reducing the cost of such a plant. Similarly, the same electrical machine can be used both as a generator as well as a motor by reversing the poles. The provision of such a scheme helps considerably in improving the load factor of the power system.(4) Tidal plantsTidal plants for generation of electric power are the recent and modern advancements, and essentially work on the principle that there is a rise in seawater during high tide period and a fall during the low ebb period. The water rises and falls twice a day; each fall cycle occupying about 12 hours and 25 minutes. The advantage of this rise and fall of water is taken in a tidal plant. In other words, the tidal range, i.e. the difference between high and low tide levels is utilized to generate power. This is accomplished by constructing a basin separated from the ocean by a partition wall and installing turbines in opening through this wall.Water passes from the ocean to the basin during high tides, and thus running the turbines and generating electric power. During low tide,the water from the basin runs back to ocean, which can also be utilized to generate electric power, provided special turbines which can generate power for either direction of flow are installed. Such plants are useful at places where tidal range is high. Rance power station in France is an example of this type of power station. The tidal range at this place is of the order of 11 meters. This power house contains 9 units of 38,000 kW.4.Hydro-plants or hydroelectric schemes may be classified on the basis of operating head on turbines as follows: ①low head scheme (head<15m),②medium head scheme (head varies between 15m to 60 m) ,③high head scheme (head>60m). They are described below:(1) Low head scheme.A low head scheme is one which uses water head of less than 15 meters or so. A run off river plant is essentially a low head scheme, a weir or a barrage is constructed to raise the water level, and the power house is constructed either in continuation with the barrage or at some distance downstream of the barrage, where water is taken to the power house through an intake canal.(2) Medium head schemeA medium head scheme is one which used water head varying between 15 to 60 meters or so. This scheme is thus essentially a dam reservoir scheme, although the dam height is mediocre. This scheme is having features somewhere between low had scheme and high head scheme.(3) High head scheme.A high head scheme is one which uses water head of more than 60m or so. A dam of sufficient height is, therefore, required to be constructed, so as to store water on the upstream side and to utilize this water throughout the year. High head schemes up to heights of 1,800 meters have been developed. The common examples of such a scheme are: Bhakra dam in (Punjab), Rihand dam in (U.P.), and Hoover dam in (U.S.A), etc.The naturally available high falls can also be developed for generating electric power. The common examples of such power developments are: Jog Falls in India, and Niagara Falls in U.S.A.水轮机和水力发电摘要水的能量可以通过三种基本方法来获得:利用水的重力作用、水的压力作用或水的流速作用,或者其中任意两种或全部三种作用的组合。

水利水电工程专业土石坝的评估和修复毕业论文外文文献翻译及原文

水利水电工程专业土石坝的评估和修复毕业论文外文文献翻译及原文

毕业设计(论文)外文文献翻译文献、资料中文题目:土石坝的评估和修复文献、资料英文题目:文献、资料来源:文献、资料发表(出版)日期:院(部):专业:班级:姓名:学号:指导教师:翻译日期: 2017.02.14附录一外文翻译英文原文Assessment and Rehabilitation of Embankment DamsNasim Uddin, P.E., M.ASCE1Abstract:A series of observations, studies, and analyses to be made in the field and in the office are presented to gain a proper understanding of how an embankment dam fits into its geologic setting and how it interacts with the presence of the reservoir it impounds. It is intended to provide an introduction to the engineering challenges of assessment and rehabilitation of embankments, with particular reference to a Croton Dam embankment.DOI: 10.1061/(ASCE)0887-3828(2002)16:4(176)CE Database keywords: Rehabilitation; Dams, embankment; Assessment.IntroductionMany major facilities, hydraulic or otherwise, have become very old and badly deteriorated; more and more owners are coming to realize that the cost of restoring their facilities is taking up a significant fraction of their operating budgets. Rehabilitation is, therefore, becoming a major growth industry for the future. In embankment dam engineering, neither the foundation nor the fills arepremanufactured to standards or codes, and their performance correspondingly is never 100% predictable. Dam engineering—in particular, that related to earth structures—has evolved on many fronts and continues to do so, particularly in the context of the economical use of resources and the determination of acceptable levels of risk. Because of this, therefore, there remains a wide variety of opinion and practice among engineers working in the field. Many aspects of designing and constructing dams will probably always fall within that group of engineering problems for which there are no universally accepted or uniquely correct procedures.In spite of advances in related technologies, however, it is likely that the building of embankments and therefore their maintenance, monitoring, and assessment will remain an empirical process. It is, therefore, difficult to conceive of a set of rigorous assessment procedures for existing dams, if there are no design codes. Many agencies (the U.S. Army Corps of Engineers, USBR, Tennessee Valley Authority, FERC, etc.) have developed checklists for field inspections, for example, and suggested formats and topics for assessment reporting. However, these cannot be taken as procedures; they serve as guidelines, reminders, and examples of what to look for and report on, but they serve as no substitute for an experienced, interested, and observant engineering eye. Several key factors should be examined by the engineer in the context of the mandate agreed upon with the dam owner, and these together with relevant and appropriate computations of static and dynamic stability form the basis of the assessment. It is only sensible for an engineer to commit to the evaluation of the condition of, or the assessment of, an existing and operating dam if he/she is familiar and comfortable with the design and construction of such things and furthermore has demonstrated his/her understanding and experience.Rehabilitation MeasuresThe main factors affecting the performance of an embankment dam are (1)seepage; (2)stability; and (3) freeboard. For an embankment dam, all of these factors are interrelated. Seepage may cause erosion and piping, which may lead to instability. Instability may cause cracking, which, in turn, may cause piping and erosion failures. The measures taken to improve the stability of an existing dam against seepage and piping will depend on the location of the seepage (foundation or embankment), the seepage volume, and its criticality. Embankment slope stability is usually improved by flattening the slopes or providing a toe berm. This slope stabilization is usually combined with drainage measures at the downstream toe. If the stability of the upstream slope under rapid drawdown conditions is of concern, then further analysis and/or monitoring of resulting pore pressures or modifications of reservoir operationsmay eliminate or reduce these concerns. Finally, raising an earth fill dam is usually a relatively straightforward fill placement operation, especi ally if the extent of the raising is relatively small. The interface between the old and new fills must be given close attention both in design and construction to ensure the continuity of the impervious element and associated filters. Relatively new materials, such as the impervious geomembranes and reinforced earth, have been used with success in raising embankment dams. Rehabilitation of an embankment dam, however, is rarely achieved by a single measure. Usually a combination of measures, such as the installation of a cutoff plus a pressure relief system, is used. In rehabilitation work, the effectiveness of the repairs is difficult to predict; often, a phased approach to the work is necessary, with monitoring and instrumentation evaluated as the work proceeds. In the rehabilitation of dams, the security of the existing dam must be an overriding concern. It is not uncommon for the dam to have suffered significantdistress—often due to the deficiencies that the rehabilitation measures are to address.The dam may be in poor condition at the outset and may possibly be in a marginally stable condition. Therefore, how the rehabilitation work may change the present conditions, both during construction and in the long term, must be assessed, to ensure that it does not adversely affect the safety of the dam. In the following text, a case study is presented as an introduction to the engineering challenges of embankment rehabilitation, with particular reference to the Croton Dam Project.Case StudyThe Croton Dam Project is located on the Muskegon River in Michigan. The project is owned and operated by the Consumer Power Company. The project structures include two earth embankments, a gated spillway, and a concrete and masonry powerhouse. The earth embankments of this project were constructed of sand with concrete core walls. The embankments were built using a modified hydraulic fill method. This method consisted of dumping the sand and then sluicing the sand into the desired location. Croton Dam is classified as a ‗‗h igh-hazard‘‘ dam and is in earthquake zone 1. As part of the FERC Part 12 Inspection (FERC 1993), an evaluation of the seismic stability was performed for the downstream slope of the left embankment at Croton Dam. The Croton Dam embankment was analyzed in the following manner. Soil parameters were chosen based on standard penetration (N) values and laboratory tests, and a seismic study was carried out to obtain the design earthquake. Using the chosen soil properties, a static finite-element study was conducted to evaluate the existing state of stress in the embankment. Then a one-dimensional dynamic analysis was conducted to determine the stress induced by the design earthquake shaking. The available strength was compared withexpected maximum earthquake conditions so that the stability of the embankment during and immediately after an earthquake could be evaluated. The evaluation showed that theembankment had a strong potential to liquefy and fail during the design earthquake. The minimum soil strength required to eliminate the liquefaction potential was then determined, and a recommendation was made to strengthen the embankment soils by insitu densification.Seismic EvaluationTwo modes of failure were considered in the analyses—namely, loss of stability and excessive deformations of the embankment. The following analyses were carried out in succession: (1) Determination of pore water pressure buildup immediately following the design earthquake; (2) estimation of strength for the loose foundation layer during and immediately following the earthquake; (3) analysis of the loss of stability for postearthquake loading where the loose sand layer in the embankment is completely liquefied; and (4) liquefaction impact analysis for the loose sand layer for which the factor of safety against liquefaction is unsatisfactory.Liquefaction Impact AssessmentBased on the average of the corrected SPT value and cyclic stress ratio (Tokimatsu and Seed 1987), a total settlement of the 4.6 m(15 ft) thick loose embankment layer due to complete liquefaction was found to be 0.23 m (0.75 ft).Permanent Deformation AnalysisBased on a procedure by Makdisi and Seed (1977), permanent deformation can be calculated using the yield acceleration, and the time history of the averagedinduced acceleration. Since the factor of safety against flow failure immediately following theearthquake falls well short of that required by FERC, the Newmark type deformation analysis is unnecessary. Therefore, it can be concluded that the embankment will undergo significant permanent deformation following the earthquake, due to slope failure in excess of the liquefaction-induced settlement of 0.23 m (0.75ft).Embankment RemediationBased on the foregoing results, it was recommended to strengthen the embankment by in situ densification. An analysis was carried out to determine the minimum soil strength required to eliminate the liquefaction potential. The analysis was divided into three parts, as follows. First, a slope stability analysis @using the computer program PCSTABL (Purdue 1988)# of the downstream slope of the left embankment was conducted. Strength and geometric parameters were varied in order to determine the minimum residual shear strength and minimum zone of soil strengthening required for a postearthquake stability factor of safety, (FS)>1.Second, SPT corrections were made. The minimum residual shear strength correlates to a corrected/normalized penetrationresistance value (N1) of 60. From this value, a backcalculation was performed to determine the minimum field measure standard penetration resistance N values (blows per foot). Third, liquefaction potential was reevaluated based on the minimum zone of strengthening and minimum strength in order to show that if the embankment is strengthened to the minimum value, then the liquefaction potential in the downstream slope of the left embankment will, for all practical purposes, be eliminated.ConclusionKey factors to be considered in dam assessment and rehabilitation are the completeness of design, construction, maintenance and monitoring records, and the experience, background, and competence of the assessing engineer. The paper presents a recently completed project to show that the economic realization of this type of rehabilitation inevitably rests to a significant degree upon the expertise of the civil engineers.ReferencesDuncan, J. M., Seed, R. B., Wong, K. S., and Ozawa, U. (1984). ‗‗FEADAM: A computer program for finite element analysis of dams.‘‘ GeotechnicalEngineering Research Rep. No. SU/GT/84-03,Dept. of Civil Engineering,Stanford Univ., Stanford, Calif.FERC. (1993). ‗‗Engineering guidelines for the evaluation of hydropower projects.‘‘ 0119-2.Makdisi, F. I., and Seed, H. B. (1977). ‗‗A simplified procedure forestimatingea rthquake induced deformations in dams and embankments.‘‘ Rep. No. EERC 77-19, Univ. of California, Berkeley, Calif.Purdue Univ. (1988). ‗‗PCSTABL: A computer program for slope stability analysis.‘‘ Rep., West Lafayette, Ind.Schnabel, P. B., Lysmer, J, an d Seed, H. B. (1972). ‗‗SHAKE: A computer program for earthquake response analysis of horizontally layered site.‘‘ Rep. No. EERC72-12, Univ. of California, Berkeley, Calif.Seed and Harder. (1990). ‗‗An SPT-based analysis of cyclic pore pressure generation and undrained residual strength.‘‘ Proc., H. Bolton Seed Memorial Symp., 2, 351–376.Tokimatsu, K., and Seed, H. B. (1987). ‗‗Evaluation of settlements of sands due to earthquake shaking.‘‘ J. Geotech. Eng., 113(8), 861–878.中文翻译土石坝的评估和修复摘要:在野外实地、办公室里已进行的一系列的观察,研究,分析,使本文获得了对石坝如何适应其地质环境,以及如何与水库相互影响的正确的认识。

水利水电工程专业外文翻译、英汉互译、中英对照

水利水电工程专业外文翻译、英汉互译、中英对照

水利水电工程专业外文翻译、英汉互译、中英对照毕业设计,论文,外文翻译题目姚家河水电站溢流坝及消能工优化设计专业水利水电工程使用CFD模型分析规模和粗糙度对反弧泄洪洞的影响12 作者 Dae Geun Kimand Jae Hyun Park摘要在这项研究中,利用CFD模型、FLOW-3D模型详细调查流量特性如流量、水面、反弧溢洪道上的峰值压力,并考虑到模型规模和表面粗糙度对速度和压力的垂直分布特征的影响,因此,在领域中被广泛验证和使用。

由于表面粗糙度数值的误差是微不足道的,对于流量,水面平稳,波峰压力影响较小。

但是我们只是使用长度比例小于100或200在可接受的误差范围的建筑材料一般粗糙度高度和规模效应的模型,最大速度在垂直的坐标堰发生更严重的粗糙度和规模效应。

原型的速度比缩尺比模型的更大,但现却相反1的。

在任何一节的最大速度略有降低或者表面粗糙度和长度的比例增加。

最大速度出现在上游水头的增加几乎呈线性增加溢洪道前的距离和位置较低的垂直位置位上。

关键词:FLOW-3D,反弧溢洪道,粗糙度效应,规模效应1.简介工程师在大多数情况下都选着设计建造具有过流高效、安全地反弧溢洪道,并且它在使用过程中具有良好的测量能力。

反弧溢洪道的形状是从较高顶堰的直线段流到半径R的网弧形段,在反弧附近的大气压力超过设计水头。

在低于设计水头时波峰阻力减少。

在高水头的时候,顶堰的大气压较高产生负压使水流变得更缓。

虽然这是关于一般反弧从上游流量条件下的变化、修改的波峰形状或改变航的形状和其流动特性的理解,但是道由于局部几何性质等的标准设计参数的偏差都会改变的水流的流动性,影响的分析结果。

物理模型被广泛的用来确定溢洪道非常重要的大坝安全。

物理模型的缺点是成本高,它可能需要相当长的时间得到的结果。

此外,由于规模效应的误差的严重程度增加原型模型的大小比例。

因此在指导以正确的模型细节时,计算成本相对较低物理建模、数值模拟,即使它不能被用于为最终确定的设计也是非常宝贵的资料。

水利水电工程中英文对照外文翻译文献

水利水电工程中英文对照外文翻译文献

中英文对照外文翻译文献(文档含英文原文和中文翻译)译文:研究钢弧形闸门的动态稳定性摘要由于钢弧形闸门的结构特征和弹力,调查对参数共振的弧形闸门的臂一直是研究领域的热点话题弧形弧形闸门的动力稳定性。

在这个论文中,简化空间框架作为分析模型,根据弹性体薄壁结构的扰动方程和梁单元模型和薄壁结构的梁单元模型,动态不稳定区域的弧形闸门可以通过有限元的方法,应用有限元的方法计算动态不稳定性的主要区域的弧形弧形闸门工作。

此外,结合物理和数值模型,对识别新方法的参数共振钢弧形闸门提出了调查,本文不仅是重要的改进弧形闸门的参数振动的计算方法,但也为进一步研究弧形弧形闸门结构的动态稳定性打下了坚实的基础。

简介低举升力,没有门槽,好流型,和操作方便等优点,使钢弧形闸门已经广泛应用于水工建筑物。

弧形闸门的结构特点是液压完全作用于弧形闸门,通过门叶和主大梁,所以弧形闸门臂是主要的组件确保弧形闸门安全操作。

如果周期性轴向载荷作用于手臂,手臂的不稳定是在一定条件下可能发生。

调查指出:在弧形闸门的20次事故中,除了极特殊的破坏情况下,弧形闸门的破坏的原因是弧形闸门臂的不稳定;此外,明显的动态作用下发生破坏。

例如:张山闸,位于中国的江苏省,包括36个弧形闸门。

当一个弧形闸门打开放水时,门被破坏了,而其他弧形闸门则关闭,受到静态静水压力仍然是一样的,很明显,一个动态的加载是造成的弧形闸门破坏一个主要因素。

因此弧形闸门臂的动态不稳定是造成弧形闸门(特别是低水头的弧形闸门)破坏的主要原是毫无疑问。

基于弧形闸门结构和作用力的特点,研究钢弧形闸门专注于研究弧形闸门臂的动态不稳定。

在1980年的,教授闫世武,教授张继光公认的参数振动引起的弧形闸门臂动态不稳定的是原因之一。

他们提出了一个简单的分析方法,近年来,在一些文献中广泛地被引用进来调查。

然而,这些调查的得到都基于模型,弧形闸门臂被视为平面简单的梁,由于弧形弧形闸门是一个复杂的空间结构,三维效果非常明显,平面简单的梁的模型无法揭示这个空间效果,并不能精确的体现弧形闸门臂的动态不稳定性,本文提出一种计算方法用于分析弧形闸门的动态不稳定。

翻译文献

翻译文献

通过在三峡水电站调峰(高峰调节)对两坝间河段通航条件的影响摘要为了充分发挥三峡电站的调峰容量,减少碰撞时通过在三峡水电站( TGHY )调峰运行航运,本文进行了日常监管模式,在调峰时的电站汛期枯水季节和模式1:110物理模型的初步研究。

这项研究的结果表明,由于非定常流动中产生的水之间的上述两个水坝在tghs日调节低流量期间对通航的影响是有限的,调节流量、调节容量比较小。

但在汛期,两调峰幅度和tghs流量波动幅度大。

因此,沿着河流流速,比降和水位波动沿河道之间两座大坝,急剧增加的电站调峰过程中在低流量的季节与比较。

当每日平均流量和调峰能力达到或超过20000立方米/ s和800万分别千瓦,流速和两坝间水课程重点浅滩梯度比超过一个10000吨船队的允许值。

因此,上行船很难航行。

关键词:三峡水电站( TGHS ) ;物理模型;汛期调峰,调峰能力;通航条件1 。

介绍长江是中国最大的河,河的干线航道是唯一的航道交通运输的大动脉,贯穿东,中部和西部地区的国家。

七省和两个城市沿河账户达到以上的经济总量的40%的国量。

长江干线航道进行80%和83%的运输量铁矿石和煤炭的钢铁厂和火电站分别沿着河。

不不仅发挥了重要的领导在散货和集装箱货物运输的作用,它还支持和促进有效的重点集中区的形成和发展沿江工业,如冶金,化工,汽车,电力农业,等近年来,电力市场的消费结构发生了显著的变化。

随着电网峰谷差,调峰矛盾变得尖锐和有一个tghs需要采取在一定范围内的调峰能力。

tghs有优势,因为它位于调峰在区域电力负荷中心,具有较大的装机容量和丰富的流量,但程度的影响的非定常流动排出调峰过程中的导航是一个伟大的关注自tghs坝位于长江干流上的运输重,此外,葛洲坝水电站(GHS)是建立在西陵峡38km出口tghs坝下游的。

为了解影响目的对通航条件在非定常流排放高峰两坝间tghs与GHS 38公里河段调峰运行在tghs为了开发减轻影响的措施和对策,研究低流量的季节调峰汛期日调节tghs 期间已经做了一个正常的液压模型1:110河段两坝间。

水利工程毕业设计外文翻译--三峡水利枢纽工程

水利工程毕业设计外文翻译--三峡水利枢纽工程

附录一:外文翻译The Three Gorges ProjectsFirst. The dam site and basic pivot disposalThe Three Gorges Projects is select to be fixed on San Dou Ping in Yichang, located inabout 40 kilometers of the upper reaches of key water control project of Ge Zhou Ba which was built. River valley, district of dam site, is widen, slope, the two sidesof the bank is relatively gentlely. In the central plains have one island (island, fort of China,), possess the good phased construction water conservancy diversion condition. The foundation of pivot building is the hard and intact body of granite. Have built Yichang and gone to stride bridge that place of 4 kilometers in the about 28 -km-long special-purpose expressway of building site and dam low reaches --West Yangtze Bridge of imperial tomb. Have also built the quay of district of a batch of dams. The dam district possesses the good traffic condition.Two. Important water conservancy project buildings1. damThe dam is a concrete gravity dam, which is 2309 meters long, it’s height is 185 meters , the dam is 181 meters high the most. Release floodwater dam section lie riverbed, 483 of the total length, consist of 22 form hole and 23 release floodwater in the deep hole, among them deep hole is imported 90 meters , the mouth size of hole is 7*9 meters; Form hole mouth is 8 meter wide, overflow weir is 158 meters, form hole and deep hole adopt nose bank choose, flow way go on and can disappear. Dam section lies in and releases floodwater on a section of both sides of the dam in the hydropower station, there are hydropower stations that enter water mouth. Enter water mouth baseplate height 108 meters. Pressure input water pipeline for carry person who in charge of, interior diameter 12.40, adopt the armored concrete to receive the strength structure. Make and let out flow of 102500 cubic meters per second the most largely in the dam site while checking the flood.2. power stationsThe power stations adopt the type after the dam to assign the scheme, consist oftwo groups of factory buildings on left, right and underground factory building altogether. Install 32 sets of hydroelectric generating set together, 14 factory buildings of left bank among them, 12 factory buildings of right bank, 6 underground factory buildings. The hydraulic turbine, in order to mix the flowing type, the specified capacity of the unit of the unit is 700,000 kilowatts.3. open up to navigation buildingThe open up to navigation buildings include permanent lock and ship lift (of the the technological public relations, the steel cable that plans to be replaced with spiral pole technology in the original plan promotes technology), lie in the left bank. Permanent lock double-line five continuous chain of locks. Single grades of floodgate room effective size for 280*34*5, can pass the 10,000 ton-class fleet. The promoting type for single track first grade vertically of the ship lift is designed, it is 120*18*3.5 meters to bear the effective size of design of railway carriage or compartment of ship, can pass a combination vessel of 3000 tons once. Total weight is 11800 tons to bear the design of railway carriage or compartment of ship when operating, it is 6000 newtons to always promote strength.Three.The major project amount and arranges in time limit The subject building of the project and major project amount of the water conservancy diversion project are: Excavate 102,830,000 cubic meters in cubic metre of earth and stone, fill out and build 31,980,000 cubic meters in cubic metre of earth and stone, concrete builds 27,940,000 cubic meters, 463,000 tons of reinforcing bars, make and fit 32 with hydroelectric generating set. All project construction tasks were divided into three stages and finished, all time limit was 17 years. The first stage (1993-1997 year) is preparation of construction and the first stage of the project, it takes 5 years to construct, regard realizing damming in the great river as the sign. The second stage (1998-2003 year) is the second stage, it takes 6 years to construct, lock as initial conservation storage of the reservoir, the first batch of aircrews generate electricity and is open up to navigation with the permanent lock as. The third stage (2004-2009 year) is the third stage of the project, it takes 6 years to construct, regard realizing the sign all aircrews generate electricity and finish building with all of multi-purpose project as. One, two project finish as scheduled already, the third stageof the project in inside the plan to construct too, ship lift tackle key problems of not going on intensely.Four. Enormous benefit of the Three Gorges Projects The Three Gorges Projects is the greatest water control project in China ,also in the world , it is the key project in controlling and developing the Changjiang River. The normal water storage level of the Three Gorges Projects reservoir is 175 meters, installed capacity is 39,300 million cubic meters; The total length of the reservoir is more than 600 kilometers, width is 1.1 kilometers on average; The area of the reservoir is 1084 sq. km.. It has enormous comprehensive benefits such as preventing flood, generating electricity, shipping,etc..1. prevent floodPrimary goal of building the Three Gorges Projects is to prevent flood . The key water control project in Sanxia is the key project that the midstream and downstream of the Changjiang River prevent flood in the system. Regulated and stored by the reservoir of Sanxia, form the capacity of reservoir in the upper reaches as river type reservoir of 39,300 million cubic meters, can regulate storage capacity and reach 22,150 million cubic meters, can intercept the flood came above of Yichang effectively, cut down flood crest flow greatly, make Jingjiang section prevent flood standard meet, improve from at present a about over ten years to once-in-a-hundred-year. Meet millennium first special great flood that meet, can cooperate with Jingjiang flood diversion partition application of flood storage project, the crushing calamity of preventing the occurrence of both sides of section of Jingjiang and bursting in the main dike, lighten midstream and downstream losing and flood threat to Wuhan of big flood, and can create conditions for administration of Dongting Hu district.2. generates electricityThe most direct economic benefits of the Three Gorges Projects is to generate electricity . Equilibrate the contradiction that contemporary China develops economic and serious energy shortage at a high speed, the hydroelectric resources that a clean one can be regenerated are undoubtedly optimum choices. The total installed capacity of power station of Sanxia is 18,200,000 kilowatts, annual average generation is84,680 million kilowatt hours. It will offer the reliable, cheap, clean regenerated energy for areas such as East China, Central China and South China of economic development, energy deficiency,etc.It play a great role in economic development and environmental pollution of reducing.Electric power resource that the Three Gorges Projects offers, if given a workforce of electricity generation by thermal power, mean building 10 more thermal power plants of 1,800,000 kilowatts, excavate more 50 million tons of raw coals every year on average. Besides environment of influencing of the waste residue, it will also discharge a large number of carbon dioxide which form the global greenhouse effects every year, cause the sulfur dioxide of acid rain, poisonous gas carbon monoxide and nitrogen oxide. At the same time, it will also produce a large amount of floating dust, dustfall,etc… Thermal power plant and abandon dreg field extensive occupation of land seize more land from East China, Central China area that have a large population and a few land just originally this. This not only makes China bear the pressure that greater environment brings in the future, cause unfavorable influence on the global environment too.3. shippingSanxia reservoir improve Yichang go to Chongqing channel of the Changjiang River of 660 kilometers notably, the 10,000 ton-class fleet can go to the harbour of Chongqing directly. The channel can rise to 50 million tons from about 10 million tons at present through ability in one-way year, transporting the cost can be reduced by 35-37%. Unless until reservoir regulate, Yichang low water flows minimum seasons downstream,whose name is can since at present 3000 cubic meters /second improve until 5000 cubic meters per above second, the shipping condition get greater improvement too to enable the Changjiang River in low water season of midstream and downstream.Five.The questions in building the Three Gorges Projects1. silt issuethe Changjiang River Yichang Duan Nian amount of sand failed 530 million tons, silt the reservoir of Sanxia up. The reservoir blocks water level is 175 meters high, installed capacity is 39,300 millionm3 normally,its die water level is 145 meters, theminimum capacity of a reservoir is 17,200 million m3, storage capacity 22,100 million m3, the conservation storage regulates the capacity of reservoir 16,500 million m3. The operation scheme of the reservoir is: Limit height is 145 meters of water level, in flood season, meet flood adjust big under 56700m3 per second, and power station smooth to let out through deep hole over 3 years, can reduce the sand of the reservoir to deposit. Great flood comes, the reservoir is adjusted bigly, still put and let out 56700m3per second; Deposit towards the reservoir after the flood. The reservoir begins conservation storage, between about two months and normal water storage level 175 meters high in September. The water level of the storehouse is dropped to 155 meters high before the flood next year, utilize conservation storage to generate electricity. In 155 meters water level, can keep the river shipping of Sichuan. By flood season, the water level was dropped to 145 meters water level again, because the flow was large at that time, could keep the river shipping of Sichuan. This is a reservoir operation scheme of innovation.2. question that the slope comes down by the bank of reservoir areaThe question that the slope comes down is through detailed geological survey by 2 reservoir area banks, there is several to come down potentially on water bank of Kuku of Sanxia, the big one can be up to millions of m3. But closest to dam site potential landslide, too far on 26kilometers, such as happen, come down, shock wave that evoke get dam disappear, reduce 2-3meters to to be high, it is safe not to influence the dam. In addition, if the slippery wave happens in the bank of the storehouse, because the reservoir is wide and deep, will not influence shipping.3. engineering question of the pivotThe pivotof Three Gorges is 185 meters high concrete gravity dampivots and 18,200,000kW, the project amount is large, but all regular projects after all, our country has more experience. The stability problem of some foundation can meet the safe requirement through dealing with. 700,000kW hydroelectric generating set, imported from foreign countries in the first batch, was made by oneself at home later. The more complicated one is lock of five grades of Line two, deep-cut in the rock bank, slope reaches 170 meters at the supreme side, the underpart floodgate room vertical 60 meters, high rock slope stability worries about. But the meticulousresearch of engineer and constructors is designed, blown up and the anchor is firm and excavating, the rock slope is steady in a long-term. There is ship lift of 3000t passenger steamer, it is the biggest in the world, in course of designing and studying, and repair the test and use the ship lift first.4.ecological environment problemThe respect useful to ecological environment of the Three Gorges Projects is: Prevent and cure downstream land and cities and towns to flood, reduce the air pollution of electricity generation by thermal power, improve some climate, the reservoir can breed fish etc.. The respect disadvantageous to ecology is: Flood more than 300,000 mu of cultivated land, ground of fruit is more than 200,000 mu, immigrants reach the highland by the storehouse, will destroy the ecological environment, the still water weakens the sewage self-purification ability, worsen water quality, influence reproduction of the wild animal,etc. in the reservoir. So is both advantageous and disadvantageous, do not hinder building the Three Gorges Projects. Should reduce being unfavorable to minimum extent, it is mainly that reservoir immigrants want to plant trees and grass, build the terraced fields, ecological environment protection, does not require the self-sufficiency of grain. Accomplish these, want making a great effort and fund. Control blowdown such as Chongqing, Fuling, Wan County, carry on sewage disposal, protect the water quality of the reservoir, protect the wild animal, set up the protection zone. Although ecological environment protection is difficult, must solve and can solve. As for the scenery of Sanxia, because the high near kilometer of rock bank, and Sanxia dam is only in fact higher than the river surface 110 meters. The scenery basically remains unchanged, the high gorge produces Pinghu, increase even more beautifully.Six. Immigrant's question in the reservoir areaThe reservoir of Sanxia will flood 632 sq. km. of land area, will involve Chongqing, 20 county (market) of Hubei. The reservoir of Sanxia floods and involves 2 cities, 11 county towns, 116 market towns; Flood or flood 1599 of industrial and mining enterprises that influence, reservoir flood line there are 24,500 hectares of cultivated land in all; Flood 824.25 kilometers of highways, 92,200 kilowatts of power stations; The area of house of flooding area is 34,596,000 square meters, totalpopulation of living in the flooding area is 844,100 people (agricultural population 361,500 people among them). Consider population growth and other factors of moving etc. two times during construction, the total population of trends of reservoir immigration allocation of Sanxia will be up to 1,130,000 people. The task is arduous, but must find a room for good immigrants, make its life improve to some extent, help immigrants to create the working condition, live plainly and struggle hard through 20 years, grow rich. Most immigrants retreat to the highland, it is nonlocal that some immigrants get. The reservoir of Sanxia will flood 632 sq. km. of land area, will involve Chongqing, 20 county (market) of Hubei. The reservoir of Sanxia floods and involves 2 cities, 11 county towns, 116 market towns; Flood or flood 1599 of industrial and mining enterprises that influence, reservoir flood line own cultivated land (suck the ground of mandarin orange) 24,500 hectares in common; Flood 824.25 kilometers of highways, 92,200 kilowatts of power stations; The area of house of flooding area is 34,596,000 square meters, The total population of living in the flooding area is 844,100 people (agricultural population 361,500 people among them). Consider population growth and other factors of moving etc. two times during construction, the total population of trends of reservoir immigration allocation of Sanxia will be up to 1,130,000 people.1.exploration and opening of the immigrants in SanxiaThe exploration of an immigrant in Sanxia and open country are in the engineering construction of Sanxia, implement immigrant's policy of the exploration, relevant people's governments organize and lead immigrants to arrange work, use immigrant's funds in a unified manner, exploit natural resources rationally, based on agriculture, the agriculture,industry and commerce combine, through many channel, many industries, multi-form, many method find a room for immigrants properly, immigrants' living standard reach or exceed originally and competently, and create the condition for long-term economic development and improvement of immigrant's living standard of reservoir area of Three Gorges. Immigrant's policy of the exploration, is a great reform of the reservoir immigrants of our country. Policy this, and reservoir area of Three Gorges immigrant put forward at the foundation of pilot project eight year in experience and lessons that immigrant work since new China setup of summarizing. At the beginning of reservoir immigrants in Sanxia, carry out exploration immigrants' principles and policies, insist the country supports, the policy is favourable, each side supports, principle of relying on one's own efforts, appeared by the government, develop local resources in a planned way, expand the capacity of placing, help, offer service of forming a complete set, wide to open up, produce the life way, make it reach " take out offing, goal that so steady as to live, can get rich progressively ". Meanwhile, the country approves reservoir area of Three Gorges as " the open economic region of Sanxia ", enjoy some special policies opening to the outside world in the coastal area, call the immigrants in Sanxia of the developed coordinated cooperation of province and city, immigrant's enterprises and relevant The factor of production has been pushed to the broader large market. The governments at all levels of reservoir area of Three Gorges have issued some development coordinated cooperation, favourable measure inviting outside investment too. Reservoir area immigrant demonstrate with open to urge, develop, in order to develop, urge benign situation that place.2. reorganization and expansion of the immigrants in SanxiaThe reorganization of immigrants in Sanxia and the expansion immigrants in Sanxia are that one involve undertaking that the society of reservoir area reconstruct, resources are recombinated, the recombinating is one of the prominent characteristics of the immigrants in Sanxia, move the fundamental difference duplicated with traditional simple compensation immigrants, former state too. Implement immigrant's policy of the exploration, must demand to combine immigrants to move, reconfigure the factor of production, thus improve the disposition efficiency of resources, form new productivity. Expand while being what is called, expansion of scale, improvement of structure even more, function strengthen improvement of quality. Look with the view of development economics and implement the course of exploration immigrants, it is the course of economic expansion of reservoir area. Exploration immigrants begin from expanding, and ending at realizing expanding, the course that the whole immigrant move and rebuild one's home is running through economic expansion, full of to the yearning that expands in the future. Certainly, in actual operation, should set out from immigrant's reality to pay attention to all, insistreason is expanded.Seven. Investment and benefit questionInvests 90,090 million yuan (1993 price) in investment and the Three Gorges Projects static behavior of benefit question, invests more than about 200 billion yuan dynamically while finishing in project. The investment source of the Three Gorges Projects is as follows, state loan, state-run hydropower station each of price of electricity raise the price 0.4-0.7 fen, power station electric rate income of Ge Zhou Ba, the electric rate income after the power station of Sanxia generates electricity wait for, the country has this financial resources to guarantee to invest in putting in place. About benefit, it is estimated it in ten years after the Three Gorges Projects is built up, total project investment principal and interest, unless including project fee and fee for immigration, can have repaid with electric rate income,it prevent flood, shipping,etc. share make the investment. And the Three Gorges Projects prevent flood, generate electricity, shipping,etc. benefit long-term, and enormous social benefit. Therefore, benefit of the Three Gorges Projects is very great, there is increase slightly to even make the investment, it is very rational too to repay service life to slightly lengthen.三峡水利枢纽工程一、坝址及基本枢纽布置三峡工程大坝坝址选定在宜昌市三斗坪,在已建成的葛洲坝水利枢纽上游约40km处。

水电站初步设计大学毕业论文英文文献翻译及原文

水电站初步设计大学毕业论文英文文献翻译及原文

毕业设计(论文)外文文献翻译文献、资料中文题目:水电站初步设计文献、资料英文题目:文献、资料来源:文献、资料发表(出版)日期:院(部):专业:班级:姓名:学号:指导教师:翻译日期: 2017.02.14Elements of electrical power station design = 电站设计基础/ M. V. Deshp ande. ─ Wheeler Publishing, 1981Where water resources are available, hydro-electrie power station are used to supply electrical energy to consumers.This type of station,however, cannot be located everywhere. First,there must be an ample quantity of water at sufficient hard, and suitable site must be available.Stream flow date for a number of years should be studied.The possibility of constructing a dam at a suitable site to store water in the catchment area and the availability of water throughout the year are decisive factors. The amount of power that can be developed depends on the quantity of water available,the rate at which it is available,the head,etc.Hydro-electric projects involve a large amount of civil engineering construction work .Often the project is a multipurpose one embracing irrigation and power,flood control and power,or flood control,navigation and power.One might imagine that hydro-electric power should be very cheap as water does not cost anything and there is no fuel cost,This ,however,is not true.To store water at enough head,it is necessary to have a dam and civil engineering construction works. This costs money,and increases investment costs and fixed costs which are not required for other types of power plants,Whenever a hydro-electric project is considered for power purposes ,it is always necessary to work out the economics comparing hydro-electric power costs with the costs for other forms of station.7.2HydrologyWhen considering the possibility of a hydro-electric project,the first requirement is to obtain data regarding the stream flow of water that would be available,and to predict the yearly possible flow from the data ,The water cycle in general consists of evaporation from seas or oceans and/or other water surfaces on the earth due to heat from the sun,the formation of moist air and clouds ,the circulation in form of rain ,hail or snow .Determination of the amount of stream flow and its variation involves a study of hydrography (or hydrology) which deals with the occurrence and under the earth's surface.The science of hydrology is based on meteorology ,geology,agricultural physics,chemistry,botany and data obtained by observation and measurement.It is necessary to calculate the mean annual rainfall in the area under consideration from a record of the annual rainfall for a number of years,say 25to30,and also to note the frequency of dry years.The precipitation or rainfall in a particular area can be measured by rain gauges at various places in the area.A rain gauge consists of a collecting cylinder which exposes a circular gauge consists of a collecting cylinder which exposes a circular surface for collecting the rain and a storage vessel in which the water is retained until measured .Recording rain gauges ,giving a continuous record,are use where possible.Frequency of precipitation is also care fully noted.A curve of precipitation in millimetres plotted against percentage of time gives a range of able for a number of years,the range of distribution of mean monthly precipitation is obtained the general character of the periodic distribution of the rainfall tends to be similar each year in each locality .There is some variation in the occurrence of rainfall from year to year ,but when the record of a number of seasons is available ,it is usually found that the occurrences of rainfall for a given month in a given locality are similar.The frequency of occurrence of a dry year or two consecutive dry years is also seen when records for a long period are available.Precipitation in a particular locality depends to a certain extent on altitude,The general and fundamental tendency is for the precipitation to increase as the altitude increases on the coastalside of a mountain range,if the locality is not far from the general sources of water vapour.Date regarding maximum rainfall in a particular area and the nature of the drainage area help in the study of possible floods in the area.Knowledge of the frequency of high rainfall in the are is also helpful in the above studies.The mean precipitation on a drainage area over a period of time can be obtained by plotting isohyets,or lines of equal precipitation,from the records available and then finding a weighted average by planimeter.Of the total precipitation ,some part of the water is lost.Sources of loss are evaporation from the water are ,soil evaporation ,interception and transpiration losses from land area.The stream flow is known when the water losses have been subtracted from the precipitation .Stream flow consists of surface flow and percolation through the ground.The various factors which affect the distribution of precipitation are meteorological conditions, drainage area characteristics,topography of land,geology of land and vegetation in the area.Evaporation is effected by heat from the sun.Temperature and relative humidity affect evaporation,and so too does wind velocity.Plants absorb moisture from the ground,giving it off to the atmosphere,the process being known as transpiration.During the process ,some water is lost,this is known as transpiration loss.Drainge area characteristics are the size and shape of the are .A small area tends to have a higher unit flood discharge than a large area.The topography of land and surface slopes affects the surface flow of water.Steep slopes tend towards a rapid and large surface flow.The size of the water area affects the losses .A large percentage of water area tends to a diminished run-off.The geological characteristics of the watershed affect run-off. Evaporation varies inversely with the porosity of soil.Percolation and water losses depend on whetner the soil is pervious or impervious.A large surface run-off is experienced when pervious ground is saturated with rainwater or when the ground is of impervious material such as rock or clay.Evaporation and percolation are increased by cultivation.Transpiration and interception losses occur owing to the presence of vegetation.To find the evaporation from a water surface a shallow pan is partly immersed in a lake or reservoir ,the evaporation being measured by the change in the water level in the pan, If the pan were placed on land, the temperature would differ from that of the lake.Humidity and wind,air and water temperatures are noted because evaporation varies with all these factors.Transpiration is estimated in a particular area in an approximate,empirical way.Changes in ground water level are found by a water-level recorder.The amount of moisture in the soil above the water table is found by measuring the electrical resistance of gypsum blocks buried at different depths in the ground.The resistance of gypsum increases as it gets drier.The soil temperature is measured by means of thermocouples placed near the gypsum blocks.In considering the factors affecting losses,the stream flow and the run-off available are determined.A drainage area and profile map is prepared.This shows the length of the river,the size and shape of the watershed,tributaries,lakes,reservoirs,etc.The watershed or drainage area is sometimes called the catchment area with respect to precipitation.7.3Stream Flow :Hydrographs:Flow Duration CurvesFor water-power studies,it is essential to know the streamflow date,over a long period if available.Daily,weekly or monthly flow data for number of years at a site help in finding the average flow data for a number of years at a site help in finding the average flow and output power that are likely to be available from the stream flow.The head available is determined by surveying the site.The minimum or lowwater flow data help in estimating the firm power that will be available at the site .The maximum flow helps in estimating the floods and in designing the spillway.Estimating the stream flow helps in determining the capacity of storage reservoir for equalising the flow to a given minimum.Knowing the maximum stream flow conditions, it is possible to estimate the necessary capacity of a flood-control reservoir for limiting the discharge to a pre-determined maximum under all conditions except extreme floods.When studing stream flow in a river,it is necessary to find the depth of the river at various sections by river gauging.The depth of the river is measured by wading in shallow water,by wire weight gauge,etc.Measurement of discharge in open channels is done by the velocity-area method or by the flow of water over a weir of known dimensions. In the velocity-area method,the discharge is obtained as the sum of the products of partial cross-sectional areas of the flowing water by the respective measured velocities in such areas.The cross-sectional areas are found by measuring the width and depth at suitably spaced points to show the shape of the river bed ,and summation of the partial areas is computed from these measurement.Velocities in different areas are measured by float or current meters.Thee other method of computing the discharge is by observing the head on a weir and the known dimensions of the weir.The discharge ,or volume rate of flow ,Q,in cubic metres per second,is given byQ=CLh3/2Where L is the length of the weir in metres ,h is the head in metres,and C is a constant.For a sharp-crested weir ,C is 1.85 approximately.Hydrographs. When a river discharge has been measured ,a curve can be plotted showing discharge in cubic metres/second against time in hours.The curve is known as a hydrograph.The ordinates may be plotted in terms of the gauge height ,the number of cubic metres per second per square kilometre,the power in kilowatts that can be developed theoretically per metre of fall,or the energy in kilowatt-hours,days or weeks.A hydrograph shows the variation of flow with time.It will also indicate the power available from the stream at different times of the day or year.It is similar to the load curve used in the study of electrical power.Hydrographs help in noting the extremes of flow more readily than the inspection of tabular values of the discharge.Hydrographs are essential in studies of the effect of storage on flow.Flow duration curve. The flow duration curve is a very convenient form of hydrograph for determining the available power at the site.It indicates the daily ,weekly or monthly flows available as ordinates plotted against percentage of time.The flow is available,one can convert the cubic metres per second per week,or other unit of time.Knowing the head at which the flow is available,one can convert the cubic metres per second per weeks,or the discharge for the period,into power in kilowatts,so that the flow duration curve becomes the load duration curve for a hydro-electric plant .If storage is available at a site upstream from the power plant ,a flow duration curve as modified by the use of storage,will be necessary.Low water flow decides the primary power that can be developed.The flow duration curve alsoshows the possible heavy flood flow and the time during which it may occur .The data are useful in designing a spillway on the dam to allow flood water to escape from the reservoir.It is easy to convert a hydrograph into a flow duration curve.The following examples illustrate the plotting of a hydrograph and flow duration curve from the flow data in terms of discharge per week.7.5 Investigation of SitePreliminary investigations are made when selecting the site for a dam,The dam should be as close to the turbines as possible,and should have maximum size of pondage and the shortest length of conduit.The ideal site will be one where the dam will have the largest catchment area to store water at a high head,and yet be economical in construction.A general reconnaissance survey is first made from the air .Topographical mapping is then carried out by detailed surveying of the area,Geological studies are made.Methods of exploring the sub-surface are by digging pits ,shafts and/or tunnels,etc.Supplementary methods used are the measurement of electrical resistivity and seismic methods of prospecting.The electrical resistivity method depends on the difference between the resistivities of the ledge rock and the overburden.The seismic method requires the measurement of the ratio of propagation of waves caused by explosion and is dependent on the difference in the elastic properties of the ledge rock and the overburden.Other methods of investigating the geological properties of rock are wash borings,churn drilling,rotary core drilling and diamond drilling.Sub-surface explorations should be made ,and condition of soil mechanics helps a great deal in this respect.Ti is necessary to investigate the possibility and availability of construction materials in the neighbourhood,namely,earth,gravel,concrete aggregates,etc.Foundation conditions have to be studied.水电站:初步设计—I7.1介绍水电站建在有水资源的地方,用于向消费者提供电能。

水利水电专业英语论文

水利水电专业英语论文

Shimen DamProfession: Hydraulic and Hydroelectric Engineering Class & Grade: 091Student Name: Wang FuStudent Number: 200916056110Architecture and Engineering DepartmentFor the district in New Taipei City, see Shimen District.Shimen Dam is an embankment dam crossing the Dahan River in Taoyuan County, Taiwan. Serving mainly for municipal water supply and flood control, the dam creates Shimen Reservoir in the mountains south of Longtan. The construction plan was created in 1938 under Japanese rule, but was not implemented immediately because of the start of World War II. The dam was the largest in Taiwan when construction ended in 1964.Each day, Shimen supplies 1.4 million tonnes of water to residences and industry and 1.8 million tonnes of water to agriculture in Taoyuan County, Taiwan|Taoyuan County and New Taipei City. It is integral to the water supply/regulation system of northern Taiwan. The dam cost NT $4.85 billion to construct.History and siteThe dam site lies in a steep canyon of the Dahan River near the aboriginal town of Fusing, at the head of a 763 km2 catchment area. The canyon, with walls up to 500 metres high, was formerly home to the summer villa of Chiang K'ai-shek. The historic arched Amuping Stone Bridge and a nearby Earth God shrine, among other landmarks, were also covered by the Shimen Reservoir as it filled. Before the dam was built in the 1950s, the flow of到了新北市区,就能看到石门区。

水利水电工程毕业论文参考文献

水利水电工程毕业论文参考文献

水利水电工程毕业论文参考文献毕业设计论文文献综述题目论水利水电工程环境影响及对策专业水利水电工程班级2007级四班学生陈剑锋指导教师杨忠超重庆交通大学2011 年论水利水电工程的环境影响及对策摘要水利水电工程是国家基础设施建设的重要工程不仅是衡量国家经济发展水平的重要标志也是关系到经济可持续发展的重要指标。

本文将主要探讨水利水电工程建设中对环境的影响以及对策。

1 关键词水利水电生态环境影响及对策前言水利水电工程建设是实现人类社会发展进步的重要技术手段。

水利水电工程在带给人类重大社会经济效益的同时不容置疑地破坏了长期形成的稳定的生态环境。

水利水电工程一方面实现了防洪、发电、灌溉、航运等巨大社会经济效益同时在施工建设和运行过程中破坏了生态环境的平衡。

导致水土流失、植被破坏大气和噪声污染大量机械污水和生活污水排放水库工程库区水流速度减缓降低河流自净化能力污染物沉降、水温水质的变化影响水生生物种群的生存繁衍库区水位抬升致使景观文物淹没珍稀动、植物灭绝水库下游河道水文水环境改变影响水生生物种群生存灌溉引水水温降低加害农作物生长。

凡此种种有些不利影响是暂时的有些是长期的有些是明显的有些是隐性的有些是直接的有些是间接的有些是可逆的有些是不可逆的。

在环境影响方面水利水电工程具有突出的特点影响地域范围广阔影响人口众多对当地社会、经济、生态环境影响巨大外部环境对工程也同样施以巨大的影响。

深入揭示和认知这些影响规律并采取相应的防治措施扩大和保护水利水电工程对生态环境的有利影响消除或减轻对生态环境的不利影响不仅是水利水电工程技术人员和环境保护工作者的任务也是国家和社会的责任。

2 主题 1. 水利工程建设对自然环境的影响水利水电工程通常不直接产生污染问题属非污染生态项目其影响的对象主要为区域生态环境。

水利水电工程的环境影响区域一般可分为库区、大坝施工区、坝下游区。

库区的环境影响主要源于水库淹没和移民安置、水库水文情势的变化受影响最大和最为重要的通常是生物多样性、水质、水温、环境地质、景观、人群健康、土壤侵蚀、土地利用、社会经济等因子受影响的性质多数为不利影响坝下游区的环境影响主要源于大坝调蓄引起的水文情势变化受影响的主要是水文、河势、水温、水质、水生生物、湿地资源、入海河口生态环境、社会经济等因子影响的性质有利有弊影响的时间一般是长期的影响的范围因区域的特点不同各异有时可延伸至河口区。

水利水电专业毕业设计外文翻译

水利水电专业毕业设计外文翻译

毕业设计(论文)外文翻译题目水库及电力系统简介专业水利水电工程班级2007级四班学生陈剑锋指导教师杨忠超重庆交通大学2011 年RESERVOIRSWhen a barrier is constructed across some river in the form of a dam, water gets stored up on the upstream side of the barrier, forming a pool of water, generally called a reservoir.Broadly speaking, any water collected in a pool or a lake may be termed as a reservoir. The water stored in reservoir may be used for various purposes. Depending upon the purposes served, the reservoirs may be classified as follows:Storage or Conservation Reservoirs.Flood Control Reservoirs.Distribution Reservoirs.Multipurpose reservoirs.(1) Storage or Conservation Reservoirs. A city water supply, irrigation water supply or a hydroelectric project drawing water directly from a river or a stream may fail to satisfy the consumers’ demands during extremely low flows, while during high flows; it may become difficult to carry out their operation due to devastating floods. A storage or a conservation reservoir can retain such excess supplies during periods of peak flows and can release them gradually during low flows as and when the need arise.Incidentally, in addition to conserving water for later use, the storage of flood water may also reduce flood damage below the reservoir. Hence, a reservoir can be used forcontrolling floods either solely or in addition to other purposes. In the former case, it is known as ‘Flood Control Reservoir’ or ‘Single Purpose Flood Control Reservoir’, and in the later case, it is called a ‘Multipurpose Reservoir’.(2) Flood Control Reservoirs A flood control reservoir or generally called flood-mitigation reservoir, stores a portion of the flood flows in such a way as to minimize the flood peaks at the areas to be protected downstream. To accomplish this, the entire inflow entering the reservoir is discharge till the outflow reaches the safe capacity of the channel downstream. The inflow in excess of this rate is stored in stored in the reservoir, which is then gradually released so as to recover the storage capacity for next flood.The flood peaks at the points just downstream of the reservoir are thus reduced by an amount AB. A flood control reservoir differs from a conservation reservoir only in its need for a large sluice-way capacity to permit rapid drawdown before or after a flood.Types of flood control reservoirs. There are tow basic types of flood-mitigation reservoir.Storage Reservoir or Detention basins.Retarding basins or retarding reservoirs.A reservoir with gates and valves installation at the spillway and at the sluice outlets is known as a storage-reservoir, while on the other hand, a reservoir with ungated outlet is known as a retarding basin.Functioning and advantages of a retarding basin:A retarding basin is usually provided with an uncontrolled spillway and anuncontrolled orifice type sluiceway. The automatic regulation of outflow depending upon the availability of water takes place from such a reservoir. The maximum discharging capacity of such a reservoir should be equal to the maximum safe carrying capacity of the channel downstream. As flood occurs, the reservoir gets filled and discharges through sluiceways. As the reservoir elevation increases, outflow discharge increases. The water level goes on rising until the flood has subsided and the inflow becomes equal to or less than the outflow. After this, water gets automatically withdrawn from the reservoir until the stored water is completely discharged. The advantages of a retarding basin over a gate controlled detention basin are:①Cost of gate installations is save.②There are no fates and hence, the possibility of human error and negligence in their operation is eliminated.Since such a reservoir is not always filled, much of land below the maximum reservoir level will be submerged only temporarily and occasionally and can be successfully used for agriculture, although no permanent habitation can be allowed on this land.Functioning and advantages of a storage reservoir:A storage reservoir with gated spillway and gated sluiceway, provides more flexibility of operation, and thus gives us better control and increased usefulness of the reservoir. Storage reservoirs are, therefore, preferred on large rivers which require batter controlled and regulated properly so as not to cause their coincidence. This is the biggest advantage of such a reservoir and outweighs its disadvantages of being costly andinvolving risk of human error in installation and operation of gates.(3) Distribution Reservoirs A distribution reservoir is a small storage reservoir constructed within a city water supply system. Such a reservoir can be filled by pumping water at a certain rate and can be used to supply water even at rates higher than the inflow rate during periods of maximum demands (called critical periods of demand). Such reservoirs are, therefore, helpful in permitting the pumps or water treatment plants to work at a uniform rate, and they store water during the hours of no demand or less demand and supply water from their ‘storage’ during the critical periods of maximum demand.(4) Multipurpose Reservoirs A reservoir planned and constructed to serve not only one purpose but various purposes together is called a multipurpose reservoir. Reservoir, designed for one purpose, incidentally serving other purpose, shall not be called a multipurpose reservoir, but will be called so, only if designed to serve those purposes also in addition to its main purpose. Hence, a reservoir designed to protect the downstream areas from floods and also to conserve water for water supply, irrigation, industrial needs, hydroelectric purposes, etc. shall be called a multipurpose reservoir.水库拦河筑一条像坝的障碍时,水就被拦蓄在障碍物的上游并形成水塘.通常称之为水库。

水利水电工程专业标准闸门的底流毕业论文外文文献翻译及原文

水利水电工程专业标准闸门的底流毕业论文外文文献翻译及原文

毕业设计(论文)外文文献翻译文献、资料中文题目:标准闸门的底流文献、资料英文题目:文献、资料来源:文献、资料发表(出版)日期:院(部):专业:班级:姓名:学号:指导教师:翻译日期: 2017.02.14外文原文Experiments in Fluids 27 (1999) 339—350 Springer-Verlag 1999Underflow of standard sluice gateA.Roth, W. H. Hager1. IntroductionGates are a hydraulic structure that allows regulation of an upstream water elevation. Among a wide number of gate designs, the so-called standard gate with a vertical gate structure containing a standard crest positioned in an almost horizontal smooth rectangular channel has particular significance in low head applications. Surface roughness of both the channel and the gate is small and thus insignificant. Standard gates are used both in laboratories and in irrigation channels, large sewers or in hydraulic structures. Compared to overflow structures, or in particular to the sharp-crested weir, standard gates have received scarce attention. The knowledge is particularly poor regarding the basic hydraulics, whereas studies relating to vibration of these gates are available. The present project describes new findings on standard gate flow, involving: (1) Scale effects; (2) Coefficient of discharge; (3) Surface Ridge; (4) Features of shock waves; (5) Velocity field; (6) Bottom and gate pressure distributions; (7) Corner vortices; and (8) Vortex intensities. A novel device to reduce shock waves in the downstream channel is also proposed.2. Present knowledgeThe present knowledge on gates was recently summarized by Lewin (1995). There is a short chapter on vertical gates containing some information on discharge and contraction coefficients,with a relatively large scatter of data. This reflects the present state, and gate flow is far from being understood from this point of view, therefore. Historical studies on underflow gates are available, and it is currently a common belief that the discharge character is tics of vertical gates have been detailed in the past century. This is definitelynot the case, because of the accuracy of discharge measurement, and the small hydraulic models often used. Well known approaches include those of Boileau (1848), Bor-nemann (1871, 1880), containing summaries of the experiments of Lesbros et al. Haberstroh (1890), Gibson (1920),Hurst and Watt (1925), Keutner (1932, 1935), Fawer (1937),Escande(1938), Gentilini(1941), and Smetana(1948). In these historical experimental studies, the exact geometrical configurations are often poorly specified, and the data are not always available. Details of gate fixation are also not described. The first modern study relating to free gate flow was conducted by Rajaratnam and Subramanya (1967). The coefficient of discharge was related to the difference of flow depths in the up- and downstream sections hCa, where o c h approach flow depth, coefficient of contraction and o c agate opening. According to observations for both free and submerged flow C is exclusively a function of the relative gated opening a/h , and C increases slightly as a/h increases,o d o starting from C0.595. The effect of skin friction was stated d to be there as on for deviations between computations based on the potential flow theory and observations. Rajaratnam (1977) conducted a second study on vertical gates in a rectangular channel 311mm wide, with gate openings between 26 and 101 mm. The axial free surface profile downstream of the gate section was shown to be self-similar. Nout sopoulos and Fanariotis (1978) pointed at the significant scatter of data relating to both coefficients of contraction and discharge. The deviations between observations and theory were attributed to the spatial flow characteristics, and the channels too small often used in laboratories. Nago(1978) made observation sina400 mm wide rectangular channel with a gate opening of 60 mm. C was found to decrease with increasing relative gate opening, from 0.595 for a/h 0 to 0.52 for a/h0.50.o o.Rajarat namand Humphries (1982) considered the free flow characteristics upstream of a vertical gate, as an addition to previous studies. The channel used was 311mm wide, and gate openings were a25 and 50 mm. Their data refer to the up streamrecirculation zone, the bottom pressure distribution, and the velocity field. Montes (1997) furnished a solution for the 2D outflow using conformal mapping, compared the coefficient of contraction with experiments, and identified deviations due to viscosity effects. The surface profiles up and downstream rom the gate section were studied, exclusively in terms of gate opening. Energy losses across a gate were related to the boundary layer development and the spatial flow features upstream from the gate. The pur- pose of this paper is to clarify several points of standard gate flow, including the discharge coefficient, the ridge position, the velocity and pressure distributions, and the shock wave development that was not at all considered up till now. These results may attract and guide numerical modelers of flow. Their results and approaches have not been reviewed here.3 ExperimentsThe experiments were conducted in a 500 mm wide and 7 m long horizontal and rectangular channel. The width of the approach channel was also reduced to b245 and 350mm.The right hand side wall and the channel bottom were coated with PVC, and the left hand side was of glass to allow for visualization. To improve the approach flow conditions, screens were inserted and surface waves were adequately reduced. The approach flow was thus without flow concentrations, smooth and always in the turbulent smooth regime. The discharge was measured with a V-notch weir located down-stream of the channel, to within $1% or $0.1 ls1,whichever was larger. An aluminum gate 499mm wide, 600mm high and 10 mm thick was used, of which the crest was of standard geometry, i.e. 2mm thick with a 45° bevel on the downstream side. The gate could be mounted with variable openings from the channel bottom. No gate slots were provided and water tightness was assured with a conventional tape. Only free gate flow was considered. The gate opening was varied from a10—120mm. Prefabricated elements of a specified height ($0.1 mm) were slid below the gate, and removed after the gate was positioned. Thisprocedure was found to be accurate compared to the opening measurement of a positioned gate. Free surface profiles were measured with a point gage of $0.5 mm reading accuracy. Due to free surface turbulence, flow depths could be read only to the nearest mm. For the shock waves described below, turbulence effects were larger, and the reading accuracy was within $2 mm. The reading position was determined with a meter along the channel; to within $5 mm. Velocities were measured with a miniature propeller meter of 8 mm internal diameter to within $5%. In addition, particle image velocimetry (PIV) was used to determine the velocity field in the vicinity of the gate section. Pressure heads on the channel bottom and on the standard gate were measuredwithamanometer, towithin$2 mm. The diameter of the pressure tapings was 1mm.The experimental program aimed at analyzing the effects of scale, the free surface profile, the development of corner eddies, the determination and reduction of shock waves, and the velocity and pressure characteristics in the gate vicinity. These items are discussed in the following.中文翻译标准闸门的底流达·罗斯,W·H·海格流体实验27 (1999)339-350 施普林格出版社 1999年1.导言闸门是一种可以控制上游水位高程的的水工建筑物。

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水利水电专业毕业论文文献翻译坝(可编辑)水利水电专业毕业论文文献翻译坝Dam The first dam for which there are reliable records was build or the Nile River sometime before 4000 B.C. It was used to divert the Nile and provide a site for the ancient city of Memphis .The oldest dam still in use is the Almanza Dam in Spain, which was constructed in the sixteenth century. With the passage of time,materials and methods of construction have improved. Making possible the erection of such large dams as the Nurek Dam, which is being constructed in the U.S.S.R. on the vaksh River near the border of Afghanistan. This dam will be 1017ft333m high, of earth and rock fill. The failure of a dam may cause serious loss of life and property; consequently, the design and maintenance of dams are commonly under government surveillance. In the United States over 30,000 dams are under the control of state authorities. The 1972 Federal Dams Safety Act PL92-367requires periodic inspections of dams by qualified experts. The failure of the Teton Dam in Idaho in June 1976 added to the concern for dam safety in the United States.1 Type of DamsDams are classified on the type and materials of construction, as gravity, arch, buttress ,and earth .The first three types are usually constructed of concrete. A gravity dam depends on its own weight for stability and it usually straight in plan although sometimes slightly curved. Arch dams transmit most of the horizontal thrust of the waterbehind them to the abutments by arch action and have thinner cross sections than comparable gravity dams. Arch dams can be used only in narrow canyons where the walls are capable of withstanding the thrust produced by the arch action. The simplest of the many types of buttress dams is the slab type, which consists of sloping flat slabs supported at intervals by buttresses. Earth dams are embankments of rock or earth with provision for controlling seepage by means of dam may be includedin a single structure. Curved dams may combine both gravity and arch action to achieve stability. Long dams often have a concrete river section containing spillway and sluice gates and earth or rock-fill wing dams for the remainder of their length The selection of the best type of dam for a given site is a problem in both engineering feasibility and cost. Feasibility is governed by topography, geology and climate. For example, because concrete spalls when subjected to alternate freezing and thawing, arch and buttress dams with thin concrete section are sometimes avoided in areas subject to extreme cold. The relative cost of the various types of dams depends mainly on the availability of construction materials near the site and the accessibility of transportation facilities. Dams are sometimes built in stages with the second or late stages constructed adecade or longer after the first stage The height of a dam isdefined as the difference in elevation between the roadway, or spillway crest, and the lowest part of the excavated foundation. However, figures quoted for heights of dams are often determined in other ways.Frequently the height is taken as the net height is taken as the net height above the old riverbed.2.Forced on dams A dam must be relatively impervious to water and capable of resisting the forces acting on it. The most important of these forces are gravity weight of dam , hydrostatic pressure, uplift, ice pressure, and earthquake forces are transmitted to the foundation and abutments of the dam, which react against the dam with an equal and opposite force, the foundation reaction. The effect of hydrostatic forces caused by water flowing over the dam may require consideration in special cases The weight of a dam is the product of its volume and the specific weight of the material. The line of action of dynamic force passes through the center of mass of the cross section. Hydrostatic force may act on both the upstream and downstream faces of the dam. The horizontal component of the hydrostatic force is the force or unit width of dam it is Where r is the specific weight of water and h is the depth of water .The line of action of this force is h/3 above the base of the dam .The vertical component of the hydrostatic force is equal to the weigh of water vertically above the face of the dam and passes through the center ofgravity of this volume of water Water under pressure inevitablyfinds its way between the dam And its foundation and creates uplift pressures. The magnitude of the uplift force depends on the character of the foundation and the construction methods. It is often assumed that the uplift pressure varies linearly from full hydrostatic pressure atthe upstream face heelto full tail-water pressure at the downstream face toe.For this assumption the uplift force U is Urh1+h2t/2Where t is the base thickness of the dam and h1and h2 are the water depths at the heel and toe of the dam,respectively. The uplift force will act through the center of area of the pressure trapezoid Actual measurements on dams indicate that the uplift force is much less than that given byEq.2Various assumption have been made regarding the distribution ofuplift pressures.The ////0>. of Reclamation sometimes assumes that the uplift pressure on gravity dams varies linearly from two-thirds of full uplift at the heel to zero at the toe. Drains are usually provided near the heel of the dam to permit the escape of seepage water and relieve uplift译文:坝据可靠记载,世界上第一座坝是公元前4000年以前在尼罗河上修建的。

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