机械工程专业英语施平没翻译课文补充.docx

第 1 次课的教学整体安排2.教学内容与讨论、思考题、作业部分可合二为一。

Couplings, Clutches, Shafts and Springs 联轴器、离合器、轴和弹簧Coupling (联轴器)A coupling is a device for connecting the ends of adjacent shafts. In machine construction, couplings are used to effect (实现) a semi-permanent (半永久性的) connection between adjacent rotating shafts. The connection is permanent in the sense that it is not meant to be broken (脱开) during the useful life of the machine, but it can be broken and restored in an emergency or when worn parts (磨损件) are replaced.There are several types of shaft couplings, their characteristics depend on the purpose for which they are used. If an exceptionally long shaft is required for a line shaft (主传动轴)in a manufacturing plant or a propeller shaft on a ship, it is made in sections (分段) that are coupled together with rigid couplings(刚性联轴器).In connecting shafts belonging to separate devices (such as an electric motor and a gearbox 齿轮箱、变速箱), precise aligning (对中、同心、同轴) of the shafts is difficult and a flexible coupling (弹性联轴器)is used. This coupling connects the shafts in such a way as to minimize the harmful effects of shaft misalignment (偏心). Flexible couplings also permit the shafts to deflect under their separate systems of loads and to move freely (float 浮动) in the axial direction (轴向) without interfering with one another. Flexible couplings can also serve to (用来) reduce the intensity (强度) of shock loads (冲击负荷) and vibrations transmitted from one shaft to another.Clutch 离合器A clutch is a device for quickly and easily connecting or disconnecting a rotatable shaft and a rotating coaxial (同心的) shaft. Clutches are usually placed between the input shaft to a machine and the output shaft from the driving motor and provide a convenient means for starting and stopping the machine and permitting the driver motor or engine to be started in an unload state (无负载的状态).The rotor (转子) (rotating member) in an electric motor has rotational inertia (转动惯量), and a torque is required to bring it up to speed (使其达到一定速度) when the motor is started. If the motor shaft is rigidly connected to a load with a large rotational inertia, and the motor is started suddenly by closing a switch, the motor may not have sufficient torque capacity to bring the motor shaft up to speed before the windings in the motor (电机中的线圈)are burned out(烧毁) by the excessive current demands (过流). A clutch between the motor and the load shafts will restrict (将…限制在)the starting torque on the motor to that required to accelerate the rotor and parts of the clutch only.On some machine tools it is convenient to let the driving motor run continuously and to start and stop the machine by operating a clutch. Other machine tools receive (获得) their power from belts (皮带) driven by pulleys (皮带轮) on intermediate shafts (中间轴) that are themselves driven by belts from long lineshafts that serve a group of machines.Shaft 轴A shaft is a rotating or stationary member, usually of (具有)circular cross section(截面), having mounted upon it such elements as gears, pulleys, flywheels(飞轮), cranks(曲轴), and other power-transmission(动力传递) elements. Shafts may be subjected to(承受) bending(弯曲), tension(扭曲),compression(压缩), or torsional loads(拉伸), acting singly or in combination with one another. When they are combined, one may expect to find both static and fatigue strength(疲劳强度) to be important design considerations, since a single shaft may be subjected to static stresses(静态应力), completely reversed stresses, and repeated stresses, all acting at the same time. The word “shaft” covers numerous variations, such as axles(短轴) and spindles. An axle is a shaft, either stationary or rotating, not subjected to a torsion load. A short rotating shaft is often called a spindle.Spring弹簧A spring is a load-sensitive, energy-storing(蓄能的) device, the chief characteristics of which are an ability to tolerate(承受) large deflections(变形) without failure and to recover(恢复) its initial size and shape when loads are removed(去掉负荷). Although most springs are mechanical and derive their effectiveness from the flexibility inherent in metallic elements(利用金属部件本身所固有的弹性), hydraulic springs and air springs are also obtainable.Springs are used for a variety of purposes, such as supplying the motive power(原动力) in clocks and watches, cushioning transport vehicles, measuring weights, restraining(约束) machine elements, mitigating(减轻) the transmission of periodic disturbing forces from unbalanced rotating machines to the supporting structure, and providing shock protection for delicate(精密的) instruments during shipment.。

Metal-Cutting ProcessMetal-cutting processes are extensively used in the manufacturing industry.They are characterized by the fact that the size of the original workpiece is sufficiently large that the final geometry can be circumscribed by it, and that the unwanted material is removed as chips, particles, and so on. The chips are a necessary means to obtain the desired tolerances, and surfaces. The amount of scrap may vary from a few percent to 70%--80% of the volume of the original work material.Owing to the rather poor material utilization of the metal-cutting processes, the anticipated scarcity of materials and energy, and increasing costs, the development in the last decade has been directed toward an increasing application of metal-forming processes. However, die costs and the capital cost of machines remain rather high; consequently, metal-cutting processes are, in many cases, the most economical, in spite of the high material waste, which only has value as scrap. Therefore, it must be expected that the material removal processes will for the next few years maintain their important position in manufacturing. Furthermore, the development of automated production systems has progressed more rapidly for metal-cutting processes than for metal-forming processes.In metal-cutting processes, the imprinting of information is carried out by a rigid medium of transfer, which is moved relative to the workpiece, and the mechanical energy is supplied through the tool. The final geometry is thus determined from the geometry of the tool and the pattern of motions of the tool and the workpiece. The basic process is mechanical: actually, a shearing action combined with fracture.As mentioned previously, the unwanted material in metal-cutting processes is removed by a rigid cutting tool, so that the desired geometry, tolerances, and surface finish are obtained. Examples of processes in this group are turning, drilling, reaming, milling, shaping, planning, broaching, grinding, honing, and lapping.Most of the cutting or machining processes are based on a two-dimensional surface creation, which means that two relative motions are necessary between the cutting tool and the work material. These motions are defined as the primary motion, which h mainly determines the cutting speed, and the feed motion, which provides the cutting zone with new material.In turning the primary motion is provided by the rotation of the workpiece, and in planning it is provided by the translation of the table; in turning the feed motion is a continuous translation of the tool, and in planning it is an intermittent translation of the tool.《机械工程专业英语》哈尔滨工业大学出版社施平金属切削加工金属切削加工在制造业中等到了广泛的应用。

Basic Concept in MechanicsThe branch of scientific analysis which deals with motions , time , and forces is called mechanics and is made up of two parts , statics and dynamics , Statics deals with the analysis of stationary systems , i.e. , those in which time is not a factor , and dynamics deals with systems which change with time .对运动、时间和作用力做出科学分析的分支称为力学。

它由静力学和动力学两部分组成。

静力学对静止系统进行分析，即在其中不考虑时间这个因素，动力学对随时间而变化的系统进行分析。

When a number of bodies are connected together to form a group or system , the forces of action and reaction between any two of the connecting bodies are called constraint forces . These forces constrain the bodies to behave in a specific manner . Forces external to this system of bodies are called applied forces .当一些物体连接在一起形成一个组合体或者系统时，任何两个相连接的物体之间的作用力和反作用力被称为约束力。

这些力约束着各个物体，使其处于特定的状态。

从外部施加到这个物体的系统的力被称为外力。

机械工程英语课文翻译Introduction在机械工程领域中，掌握英语是非常重要的技能。

本篇文章将介绍一篇机械工程英语课文的翻译，旨在帮助读者提升英语水平和理解机械工程领域的专业术语。

原文原文标题：Introduction to Mechanical Engineering原文内容：Mechanical engineering is a broad field that encompasses various aspects of engineering. It deals with the design, analysis, manufacturing, and maintenance of mechanical systems. Mechanical engineers are responsible for creating and improving the machines and systems that enable different industries to function efficiently.The field of mechanical engineering has a long history, dating back to ancient civilizations such as the Greeks and Egyptians. However, it wasn’t until the Industrial Revolution in the 18th century that mechanical engineering became a distinct discipline. This period saw the rise of factories and the need for efficient machines to drive industrial processes.Modern mechanical engineers work on a wide range of projects, from designing and constructing buildings to developing advanced robotics and aerospace systems. They utilize their knowledge of physics, mathematics, and materials science to analyze and solve complex engineering problems.翻译翻译标题：机械工程导论机械工程是一个包含各个工程学科的广泛领域。

机械专业英语英译汉(3)Automatic Screw MachinesScrew machines are similar in construction to turret lathes, except that their heads are designed to hold and feed long bars of stock. Otherwise, there is little difference between them. Both are designed for multiple tooling, and both have adaptations for identical work. Originally, the turret lathe was designed as a chucking lathe for machining small castings, forgings, and irregularly shaped workpieces.The first screw machines were designed to feed bar stock and wire used in making small screw parts. Today, however, the turret lathe is frequently used with a collet attachment, and the automatic screw machine can be equipped with a chuck to hold castings.The single-spindle automatic screw machine, as its name implies, machines work on only one bar of stock at a time. A bar 16 to 20 feet long is fed through the headstock spindle and is held firmly by a collet. The machining operations are done by cutting tools mounted on the turret and on the cross slide. When the machine is in operation, the spindle and the stock are rotated at selected speeds for different operations. If required, rapid reversal of spindle direction is also possible.In the single-spindle automatic screw machine, a specific length of stock is automatically fed thr5ough the spindle to a machining area. At this point, the turret and cross slide move into position and automatically perform whatever operations are required. After the machined piece is cut off, stock is again fed into the machining area and the entire cycle is repeated.Multiple-spindle automatic screw machines have from four to eight spindles located around a spindle carrier. Long bars of stock, supported at the rear of the machine, pass through these hollow spindles and are gripped by collets. With the single spindle machine, the turret indexes around the spindle. When one tool on the turret is working, the others are not. With a multiple spindle machine, however, the spindle itself indexes. Thus the bars of stock are carried to the various end working and side working tools. Each tool operates in only one position, but all tools operate simultaneously. Therefore, four to eight workpieces can be machined at the same time. 《机械工程专业英语》电子工业出版社施平自动螺丝车床螺丝车床在结构上与转塔车床类似，不同之处是螺丝车床的主轴头部能被设计用来夹持和送进长棒料。

机械专业英语英译汉(3)Automatic Screw MachinesScrew machines are similar in construction to turret lathes, except that their heads are designed to hold and feed long bars of stock. Otherwise, there is little difference between them. Both are designed for multiple tooling, and both have adaptations for identical work. Originally, the turret lathe was designed as a chucking lathe for machining small castings, forgings, and irregularly shaped workpieces.The first screw machines were designed to feed bar stock and wire used in making small screw parts. Today, however, the turret lathe is frequently used with a collet attachment, and the automatic screw machine can be equipped with a chuck to hold castings.The single-spindle automatic screw machine, as its name implies, machines work on only one bar of stock at a time. A bar 16 to 20 feet long is fed through the headstock spindle and is held firmly by a collet. The machining operations are done by cutting tools mounted on the turret and on the cross slide. When the machine is in operation, the spindle and the stock are rotated at selected speeds for different operations. If required, rapid reversal of spindle direction is also possible.In the single-spindle automatic screw machine, a specific length of stock is automatically fed thr5ough the spindle to a machining area. At this point, the turret and cross slide move into position and automatically perform whatever operations are required. After the machined piece is cut off, stock is again fed into the machining area and the entire cycle is repeated.Multiple-spindle automatic screw machines have from four to eight spindles located around a spindle carrier. Long bars of stock, supported at the rear of the machine, pass through these hollow spindles and are gripped by collets. With the single spindle machine, the turret indexes around the spindle. When one tool on the turret is working, the others are not. With a multiple spindle machine, however, the spindle itself indexes. Thus the bars of stock are carried to the various end working and side working tools. Each tool operates in only one position, but all tools operate simultaneously. Therefore, four to eight workpieces can be machined at the same time. 《机械工程专业英语》电子工业出版社施平自动螺丝车床螺丝车床在结构上与转塔车床类似，不同之处是螺丝车床的主轴头部能被设计用来夹持和送进长棒料。

第一课Text:It is known that metals are very important in our life. Metals have the greatest importance for industry. All machines and other engineering[7endVi5niEriN] constructions have metal[5metl] parts; some of them consist only of metal parts.众所周知，金属在我们的生活中是非常重要的，金属对于工业而言是有巨大的重要性，所有机器和其他工程构造都有金属零部件，其中一些还只能由金属组成。

There are two large groups of metals:1) Simple metal- more or less pure chemical elements[5elimEnt]2) Alloys[5AlCi]- materials consisting of a simple metal combined with some other elements.有两大类金属：（1）纯金属——或多或少的金属元素（2）合金——组成纯金属的原料结合其他元素。

About two thirds of all elements found in the earth are metals, but not all metals may be used in industry. Those metals which are used in industry are called engineering metals. The most important engineering metalis iron[5aiEn], which in the form of alloys with carbon[5kB:bEn] and other elements, finds greater use than any other metal. Metals consisting of iron combined with some other elements are known as ferrous[5ferEs] metals; all the other metals are called nonferrous[5nCn5ferEs] metals. The most important nonferrous metal arecopper[5kCpE], aluminum[E5lju:minEm], lead[li:d], zinc[ziNk], tin[tin], but all these metals are used muchless than ferrous metals, because the ferrous metals are much cheaper.在地球上发现的所有元素中，大约三分之二是金属元素，但是并不是所有的金属都能够用于工业上。

2、应力和应变在任何工程结构中独立的部件或构件将承受来自于部件的使用状况或工作的外部环境的外力作用。

如果组件就处于平衡状态,由此而来的各种外力将会为零,但尽管如此,它们共同作用部件的载荷易于使部件变形同时在材料里面产生相应的内力。

有很多不同负载可以应用于构件的方式。

负荷根据相应时间的不同可分为:(a)静态负荷是一种在相对较短的时间内逐步达到平衡的应用载荷。

(b)持续负载是一种在很长一段时间为一个常数的载荷, 例如结构的重量。

这种类型的载荷以相同的方式作为一个静态负荷; 然而,对一些材料与温度和压力的条件下,短时间的载荷和长时间的载荷抵抗失效的能力可能是不同的。

(c)冲击载荷是一种快速载荷(一种能量载荷)。

振动通常导致一个冲击载荷, 一般平衡是不能建立的直到通过自然的阻尼力的作用使振动停止的时候。

(d)重复载荷是一种被应用和去除千万次的载荷。

(e)疲劳载荷或交变载荷是一种大小和设计随时间不断变化的载荷。

上面已经提到，作用于物体的外力与在材料里面产生的相应内力平衡。

因此,如果一个杆受到一个均匀的拉伸和压缩，也就是说, 一个力,均匀分布于一截面,那么产生的内力也均匀分布并且可以说杆是受到一个均匀的正常应力,应力被定义为应力==负载 P /压力 A,因此根据载荷的性质应力是可以压缩或拉伸的,并被度量为牛顿每平方米或它的倍数。

如果一个杆受到轴向载荷，即是应力，那么杆的长度会改变。

如果杆的初始长度L和改变量△L已知，产生的应力定义如下:应力==改变长△L /初始长 L因此应力是一个测量材料变形和无量纲的物理量 ,即它没有单位;它只是两个相同单位的物理量的比值。

一般来说,在实践中,在荷载作用下材料的延伸是非常小的, 测量的应力以*10-6的形式是方便的, 即微应变, 使用的符号也相应成为ue。

从某种意义上说，拉伸应力与应变被认为是正的。

压缩应力与应变被认为是负的。

因此负应力使长度减小。

当负载移除时，如果材料回复到初始的，无负载时的尺寸时，我们就说它是具有弹性的。

Spur GearsGears , defined as toothed members transmitting rotary motion from one shaft to another , are among the oldest devices and inventions of man . In about 2600 B.C. , the Chinese are known to have used a chariot incorporating a complex series of gears . Aristotle , in the fourth century B.C. , wrote of gears as if they were commonplace . In the fifteenth century A.D. , Leonardo da Vinci designed a multitude of devices incorporating many kinds of gears .齿轮，在最古老的设备和发明人中，被定义为通过轮齿将旋转运动从一根轴传递到另一根轴，大约在公元前2600年，中国人就知道用战车组成一系列复杂的齿轮系。

西元前四世纪，亚里士多德记述了齿轮就好像是他们司空见惯的一样。

在十五世纪，达芬奇设计了大量的包含各种各样齿轮的设备。

Among the various means of mechanical power transmission (including primarily gears , belts , and chains ) , gears are generally the most rugged and durable . Their power transmission efficiency is as high as 98 percent . On the other hand , gears are usually more costly than chains and belts . As would be expected , gear manufacturing costs increase sharply with increased precision -- as required for the combination of high speeds and heavy loads , and for low noise levels . ( Standard tolerances for various degrees of manufacturing precision have been established by the AGMA , American Gear Manufacturers Association. )在众多的机械传动方式中（包括齿轮传动，带传动，链传动），一般来说，齿轮是最经久耐用的，它的能量传递效率高达98%。

机械工程英语原文+翻译完整版第一单元Types of Materials材料的类型Materials may be grouped in several ways. Scientists often classify materials by their state: solid, liquid, or gas. They also separate them into organic (once living) and inorganic (never living) materials.材料可以按多种方法分类。

科学家常根据状态将材料分为：固体、液体或气体。

他们也把材料分为有机材料(曾经有生命的)和无机材料(从未有生命的)。

For industrial purposes, materials are divided into engineering materials or nonengineering materials. Engineering materials are those used in manufacture and become parts of products.就工业效用而言，材料被分为工程材料和非工程材料。

那些用于加工制造并成为产品组成部分的就是工程材料。

Nonengineering materials are the chemicals, fuels, lubricants, and other materials used in the manufacturing process, which do not become part of the product.非工程材料则是化学品、燃料、润滑剂以及其它用于加工制造过程但不成为产品组成部分的材料。

Engineering materials may be further subdivided into: ①Metal ②Ceramics ③Composite ④Polymers, etc.工程材料还能进一步细分为：①金属材料②陶瓷材料③复合材料④聚合材料，等等。

施平机械工程专业英语教程Introduction to Mechanical EngineeringChapter 1: Introduction to Mechanical Engineering- Definition and scope of mechanical engineering- Historical background and evolution of the field- Overview of various disciplines within mechanical engineering Chapter 2: Mechanics- Principles of mechanics, including statics and dynamics- Laws of motion and their applications- Analysis of forces and moments in mechanical systems Chapter 3: Thermodynamics- Basic concepts and laws of thermodynamics- Energy and heat transfer in mechanical systems- Analysis of thermodynamic cycles and processesChapter 4: Materials Science and Engineering- Properties and behavior of materials used in mechanical engineering- Material testing and characterization methods- Selection of materials for specific applicationsChapter 5: Fluid Mechanics- Fundamentals of fluid mechanics- Analysis of fluid flow and pressure distribution- Applications of fluid mechanics in mechanical systems Chapter 6: Heat Transfer- Modes of heat transfer (conduction, convection, radiation)- Heat transfer analysis and calculations- Applications of heat transfer in mechanical systemsChapter 7: Energy Conversion and Power Systems- Energy conversion principles and devices- Analysis of power generation systems- Renewable energy sources and sustainabilityChapter 8: Machine Design and Control Systems- Design principles and methodologies for mechanical systems- Control systems and automation in mechanical engineering- Analysis and optimization of machine componentsChapter 9: Manufacturing Processes- Various manufacturing processes and methodologies- Machining, forming, casting, and joining processes- Quality control and inspection in manufacturingChapter 10: Engineering Ethics and Professionalism- Ethical considerations in engineering practice- Professional responsibility and accountability- Society and the engineer's role in sustainable development Chapter 11: Career Opportunities in Mechanical Engineering- Overview of career options and paths in mechanical engineering - Skills and qualities desired by employers- Professional organizations and resources for career advancement Chapter 12: Emerging Technologies in Mechanical Engineering- Trends and developments in the field of mechanical engineering - Introduction to advanced technologies like robotics, nanotechnology, and artificial intelligence- Potential impact of these technologies on the future of mechanical engineering.。

Gear Materials (Reading Material)齿轮材料（阅读材料）Gears are manufactured from a wide variety of materials, both metallic as well as nonmetallic.齿轮由多种种类的材料制造，包括金属材料和非金属材料。

As is the case with all materials used in design, the material chosen for a particular gear should be the cheapest available that will ensure satisfactory performance.在设计中可以使用多种材料的情况下，对于特定齿轮，应当做到选用满足使用要求下的最便宜的材料。

Before a choice is made, the designer must decide which of several criteria is most important to the problem at hand.在作出选择前，设计师必须决定在众多设计准则中哪个是当前最重要的。

If high strength is the prime consideration, a steel should usually be chosen rather than cast iron.如果高强度是第一要考虑的因素，通常就选择钢材而不选择铸铁。

If wear resistance is the most important consideration, a can be made, for problems involving noise reduction, nonmetallic. Materials perform better than metallic ones.如果耐磨性是最重要的因素，可以选用非金属材料要比金属材料更好，同时也可以解决降低噪声的问题。

第三课Overview of Engineering Mechanics工程力学概述当我们观察我们周围就会发现世界充满“物品”：机器，设备，工具；我们已经设计，建造，并使用的物品；木头，金属，陶瓷和塑料制品。

根据我们使用的经验知道，有些物品比其它物品更好；他们使用寿命较长，费用较低，噪音更低，更好看，或者更方便我们使用。

然而，在理想的情况下，每一件产品都是设计人员工具其对某些“功能要求”的理解而设计出来的，也就是说，在设计过程中，应该回答这样的问题，即“它应该具有哪种确切的功能？”在工程领域，主要功能通常是承受由于重力，惯性力，压力等作用的一些类型的载荷。

从我们居住房屋的梁到飞机机翼，都必须有一个适当的材料，尺寸，在较合理的寿命基础上具有较合理的成本并能可靠地完成其功能的产品结构连接的组合。

在实践中，工程力学方法常被应用在两个完全不同领域：(1) 任何新装置的研发都需要对其结构，尺寸，材料，载荷，耐久性，安全和成本的反复考虑。

(2) 当一个装置（意外地）发生失效后，通常需要进行研究，找出失效的原因，并找出潜在的纠正措施。

最好的设计往往都是不断排除薄弱环节的演变过程。

对许多工程师来说，上述过程既可以令人非常的陶醉又可以使人非常的愉快，更何况（有时）对我们是有利的。

对于任何实际的问题，总是缺乏足够完整和有用的信息。

我们很少准确地知道实际荷载和工作状态，因此，所做的分析工作也很少是精确的。

虽然我们的数学可以准确，全面的分析一般只能近似，而且不同技术水平的人能得到不同的解。

在工程力学研究领域，大多数问题要想得到唯一解就要充分的理想化，但应该清楚，“现实世界”远不非理想化程度，因此为了得到问题的解决方案不得不进行一些理想化假设。

我们要考虑的技术领域通常被称为“静力学”和“材料力学”，“静力学”，指的是研究作用在固定装置上的作用力，“材料力学”指的是施加到结构的力（变形，载荷限制等）的影响。

但是，事实上很多设备都不是静态的，如果与动力学有关的额外负荷被考虑了的话，那么静力学的研究方法完全适用于动态的情况，只要动态力相对静态载荷较小，系统通常被认为是静态的。

机械工程专业英语教程第一课：机械工程简介Introduction to Mechanical EngineeringSection 1: OverviewMechanical engineering is a diverse and dynamic field that encompasses the design, development, and operation of machinery, structures, and systems. This branch of engineering plays a crucial role in various industries, including automotive, aerospace, manufacturing, and energy.Section 2: Responsibilities and SkillsAs a mechanical engineer, your responsibilities will include designing and analyzing mechanical systems, conducting tests and experiments, and supervising the manufacturing process. You will also need to have a strong understanding of physics, mathematics, and computer-aided design (CAD). Additionally, problem-solving skills, attention to detail, and the ability to work well in teams are essential.Section 3: Career OpportunitiesA degree in mechanical engineering can open up a wide range of career opportunities. You could work in research and development, product design, manufacturing, or projectmanagement. Mechanical engineers are in demand in almost every industry, ensuring a stable and rewarding career path.Section 4: University CoursesTo become a mechanical engineer, it is essential to pursue a degree in mechanical engineering from a reputable university. The curriculum typically includes courses in engineering principles, materials science, thermodynamics, fluid mechanics, and mechanical design. Additionally, practical training through internships or cooperative education programs is crucial for gaining hands-on experience.Section 5: ConclusionMechanical engineering offers a challenging and rewarding career for those with a passion for solving problems and a desire to create innovative solutions. With the right education and skills, you can embark on a successful journey in the field of mechanical engineering. Remember, the possibilities are endless in this ever-evolving discipline.第二课：机械设计基础Fundamentals of Mechanical DesignSection 1: IntroductionIn this lesson, we will explore the fundamentals of mechanical design. Mechanical design involves the creation and development of physical systems and components that meet specific requirements and specifications. This processrequires a deep understanding of materials, mechanics, and engineering principles.Section 2: Design ProcessThe design process typically follows a systematic approach that includes several stages. These stages include problem identification, conceptual design, detailed design, manufacturing, and testing. Each stage involves various activities such as brainstorming, prototyping, and evaluation.Section 3: Design ConsiderationsDuring the design process, there are several important considerations to keep in mind. These include functionality, efficiency, reliability, safety, and cost-effectiveness. It is also crucial to consider the environmental impact and sustainability of the design.Section 4: Tools and SoftwareTo aid in the design process, engineers use various tools and software. Computer-aided design (CAD) software allows for precise modeling and simulation of mechanical systems. Finite element analysis (FEA) software helps in analyzing the structural integrity and performance of designs.Section 5: Case StudyTo further understand the application of mechanical design principles, we will examine a case study. This real-world example will demonstrate how the design process isimplemented to solve a specific problem and achieve desired outcomes.Section 6: ConclusionMechanical design is a critical aspect of mechanical engineering. It requires a combination of creativity, technical knowledge, and attention to detail. By mastering the fundamentals of mechanical design, you will be well-equippedto tackle complex challenges and contribute to the development of innovative solutions.以上是《机械工程专业英语教程》的课文翻译。

机械工程专业英语参考译文机械工程专业英语参考译文机械工程是一门涉及设计、制造、控制和维护机械系统的学科，涉及到许多不同的领域，包括制造业、航空航天、汽车、能源和医疗设备等。

机械工程专业英语是机械工程领域中非常重要的语言工具，以下是一些常见的机械工程专业英语词汇和短语:1. Machine Tools - 机器工具Machine tools are tools that are used to perform precision machining operations on materials. They include drills, mills, lathes, routers, and other tools that are used to create precision parts and assemblies.2. Material - 材料Material is any substance that is in a solid, liquid, or gas state. It can be made from a variety of materials, such as metals, ceramics, plastics, and papers. In engineering, material refers to the physical and chemical properties of a material that determine its behavior in a particular application.3. Design - 设计Design refers to the process of creating a plan or concept for a particular object or system. It involves analyzing the needs and requirements of a particular application, and thenusing geometry, math, and other tools to create a visual representation of the object or system.4. Tolerance - 公差Tolerance is the allowance for error or variation that is allowed in a manufacturing process. It is the amount of variation that is acceptable in a product or component before it is considered to be within specification. In engineering, tolerance refers to the accuracy with which a component or system is designed to operate.5. machinist - 机械工程师Machinist is a professional in the field of mechanical engineering who specializes in the design, construction, and maintenance of machine tools. Machinists typically work in manufacturing plants, tool and die shops, and other industrial settings.6. lathe - 车床Lathe is a machine tool that is used to machine rotationally symmetric objects, such as shafts, gears, and camshafts. It includes a bed, a turret, and a spindle that rotates the workpiece around its axis.7. milling machine - 铣床Milling machine is a machine tool that is used for precisionmachining of materials. It includes a spindle that rotates a cutting tool, which can be a carbide or other hard tool, around its axis. milling machines are commonly used for machining metals, ceramics, and other materials.8. precision - 精度Precision refers to the accuracy and reliability of a machine tool or other industrial equipment. It is the ability of a tool to produce parts or assemblies that are within specified tolerance limits, and is often measured in units of accuracy, such as microns or inches.9. toolholder - 刀具夹具Toolholder is a device that is used to hold a cutting tool in a machine tool. It typically includes a base, a support surface, and a nose that supports the tool at a desired angle and distance from the workpiece.10. fastener - 紧固件Fastener is any device that is used to join two or more objects together. They include nuts, bolts, screws, pins, and other devices that are used to secure components together. In engineering, fasteners refer to the materials and techniques used to install and secure fasteners.以上是一些机械工程专业英语词汇和短语的示例，这些词汇和短语在机械工程领域中非常重要，掌握它们可以帮助机械工程专业的学生和从业者更好地理解和应用机械工程知识。

4、工程机械概述As we look around us we see a world full of “things”: machines, devices, tools; things that we have designed, built, and used; things made of wood, metals, ceramics, and plastics. We know from experience that some things are better than others; they last longer, cost less, are quieter, look better, or are easier to use.;;情况.Ideally, however, every such item has been designed according to some set of “functional requirements” as perceived by the designers — that is, it has been designed so as to answer the question, “Exactly what function should it perform?”In the world of engineering, the major function frequently is to support some type of loading due to weight, inertia, pressure, etc.的From the beams in our homes to the wings of an airplane, there must be an appropriate melding of materials, dimensions, and fastenings to produce structures that will perform their functions reliably for a reasonable cost over a reasonablelifetime.In practice, engineering mechanics methods are used in two quite different ways: (1) The development of any new device requires an interactive, iterative consideration of form, size, materials, loads, durability, safety, and cost. (2) When a device fails (unexpectedly) it is often necessary to carry out a study to pinpoint the cause of failure and to identify potential corrective measures. Our best designs often evolve through a successive elimination of weak points.1.cost.2.To many engineers, both of the above processes can prove to be absolutely fascinating and enjoyable, not to mention (at times) lucrative.In any “real” problem there is never sufficient good, useful information; we seldom know the actual loads and operating conditions with any precision, and theanalyses are seldom exact. While our mathematics may be precise, the overall analysis is generally only approximate, and different skilled people can obtain different solutions. In the study of engineering mechanics, most of the problems will be sufficiently “idealized” to permit unique solutions, but it should be clear that the “real world” is far less idealized, and that you usually will have to perform some idealization in order to obtain a solution.在命令必须执行一些理想化获得一个解决方案。

5.1 IntroductionConventional machining is the group of machining operations that use single- or multi-point tools to remove material in the form of chips. Metal cutting involves removing metal through machining operations. Machining traditionally takes place on lathes, drill presses, and milling machines with the use of various cutting tools. Most machining has very low set-up cost compared with forming, molding, and casting processes. However, machining is much more expensive for high volumes. Machining is necessary where tight tolerances on dimensions and finishes are required.5.1 译文传统机械加工是一组利用单刃或者多刃刀具以切屑形式去除材料的加工方式。

金属切削意味着通过机械加工去除金属。

传统的机械加工都是利用不同的刀具在车床、钻床和铣床上进行的。

与成型加工、锻压和铸造工艺相比，大多数机械加工的生产准备成本都较低，然而如果是大批量生产，其成本要高得多。

当对零件的尺寸公差和光洁度要求较高时，机械加工是很有必要的。

5.2 Turning and LatheTurning is one of the most common of metal cutting operations. In turning, a workpiece is rotated about its axis as single-point cutting tools are fed into it, shearing away excess material and creating the desired cylindrical surface. Turning can occur on both external and internal surfaces to produce an axially-symmetrical contoured part. Parts ranging from pocket watch components to large diameter marine propeller shafts can be turned on a lathe.Apart from turning, several other operations can also be performed on lathe.axially ['æksiəli] adv.轴向地symmetrical [si'metrikəl] a. 对称的cylindrical [si'lindrikl] a.圆柱形的contoured ['kɔntuəd] a.显示轮廓的，与某种形体轮廓相吻合的译文:在金属切削加工操作中，车削是最常见的一种。

机械工程专业英语》参考译文高等学校机械设计制造及其自动化专业新编系列教材(供教师及学生使用)黄运尧黄威司徒忠李翠琼武汉理工大学出版社目录编译者的话………………………………第1章材料和热加工…………………第1课机械学的基本概念…………第2课塑性理论的基本假设………第3课有限元优化的应用…………第4课金属…………………………第5课金属和非金属材料…………第6课塑料和其他材料……………第7课模具的寿命和失效…………第8踩冷加工和热加工……………第9踩铸造…………………………第10课制造中的金属成形工艺…第11课缎选………………………第12课锻造的优点和工作原理…第13课焊接………………………第14课热处理……………………第二章机构和机器原理……………。

第15课机构介绍…………………。

第16课运动分析…………………．第l7课运动的综合………………—第18课凸轮和齿轮………………—第19课螺纹件，紧固件和联接件—第20课减(耐)摩擦轴承…………*第2l课斜齿轮、蜗杆蜗轮和锥齿轮第22课轴、离合器和制动器……—第三章机床………第23课机床基础第24课车床……第25课牛头刨、钻床和铣床…………第36课磨床和特种金属加工工艺……第四章切削技术和液压“………………第27课加工基础………………………第28课基本的机械加工参数…………第29课切削参数的改变对温度的影响第30课刀具的磨损…………第31课表面稍整加工机理…第32课极限和公差…………“第33课尺寸控制和表面桔整”第34课自动央具设计………“第36课变速液压装置……………—…………—策37课电液伺服系统…………。

……………。

第五章机械电子技术………………………………第38课专家系统……。

…………………………第3D课建筑机器人………………………………第40课微机为基础的机器人模拟………………第41课机器人学的定义和机器入系统…………第42课微型计算机基础(1)……………………第43课微型计算机基础(x)……………………第44课可编程控制器……………………………第45课CAD／CAM计算机辅助设计与制造…第46课计算机数控和直接数控，CNC和DNC第47课加工过程的数控—………………………第48课柔性制造系统……………—……………第仍课交互式编程系统…………………………第50课在振动分析方面的计算机技术…………策51课压力传感器………………………………第52课反馈元件…………………—……………第53课现代按制理论概述………………………第54课管理上采取了新的措施—来自福持汽第六章英文科技文献和专利文献的查阅…………6．1 常见科技文献及其查阅………………………6．2 专利文献概述…………………………………第七章英文科拉论文写作…………………………7．1 标题与摘要写法………………………………7．2 正文(body)的组织与写法…………………7．3 致谢、附录及参考文献………………—……参考文献………………………………………………第1章材料和热加工机械学的基本概念功是力乘以该力作用在物体上佼物体移动的距离。