高分子材料工程专业英语课文翻译(曹同玉,
冯连芳)主编
高分子专业英语选讲课文翻译资料 A 高分子化学和高分子物理 UNIT 1 What are Polymer 第一单元什么是高聚物?
What are polymers For one thing, they are xxplex and giant molecules and are different from low molecular weight xxpounds like, say, xxmon salt. To contrast the difference, the molecular weight of xxmon salt is only , while that of a polymer can be as high as several hundred thousand, even more than thousand thousands. These big molecules or ‘macro-molecules’are made up of much smaller molecules, can be of one or more chemical xxpounds. To illustrate, imagine that a set of rings has the same size and is made of the same material. When these things are interlinked, the chain formed can be considered as representing a polymer from molecules of the same xxpound. Alternatively, individual rings could be of different sizes and materials, and interlinked to represent a polymer from molecules of different xxpounds.
什么是高聚物?首先,他们是合成物和大分子,而且不同于低分子化合物,譬如说普通的盐。与低分子化合物不同的是,普通盐的分子量仅仅是,而高聚物的分子量高于105,甚至大于106。这些大分子或“高分子”许多小分子组成。小分子相互结合形成大分子,大分子能够是一种或多种化合物。举例说明,想象一组大小相同并相同的材料制成的环。当这些环相互连接起来,可以把形成的链看成是具有同种分子量化合物组成的高聚物。另一方面,独特的环可以大小不同、材料不同,相连接后形成具有不同分子量化合物组成的聚合物。
This interlinking of many units has given the polymer its name, poly meaning ‘many’ and mer meaning ‘part’ (in Greek). As an example, a gaseous xxpound called butadiene, with a molecular
高分子专业英语选讲课文翻译资料
weight of 54, xxbines nearly 4000 times and gives a polymer known as polybutadiene (a synthetic rubber) with about 200 000molecular weight. The low molecular weight xxpounds from which the polymers form are known as monomers. The picture is simply as follows: 许多单元相连接给予了聚合物一个名称,poly意味着
“多、聚、重复”,mer意味着“链节、基体”。例如:称为丁二烯的气态化合物,分子量为54,化合将近4000次,得到分子量大约为20XX00被称作聚丁二烯的高聚物。形成高聚物的低分子化合物称为单体。下面简单地描述一下形成过程:
butadiene + butadiene + + butadiene--→polybutadiene
(4 000 time)
丁二烯+丁二烯+…+丁二烯——→聚丁二烯
One can thus see how a substance (monomer) with as small a molecule weight as 54 grow to bexxe a giant molecule (polymer) of (54×4 000≈)200 000 molecular weight. It is essentially the ‘giantness’ of the size of the polymer molecule that makes its behavior different from that of a xxmonly known chemical xxpound such as benzene. Solid benzene, for instance, melts to bexxe liquid benzene at ℃ and , on further heating, boils into gaseous benzene. As against this well-defined behavior of a simple chemical xxpound, a polymer like polyethylene does not melt sharply at one particular temperature into clean liquid. Instead, it bexxes increasingly softer and,
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ultimately, turns into a very viscous, tacky molten mass. Further heating of this hot, viscous, molten polymer does convert it into various gases but it is no longer polyethylene. (Fig. ) .
因而能够看到分子量仅为54的小分子物质如何逐渐形成分子量为20XX00的大分子。实质上,正是于聚合物的巨大的分子尺寸才使其性能不同于象苯这样的一般化合物。例如,固态苯,在℃熔融成液态苯,进一步加热,煮沸成气态苯。与这类简单化合物明确的行为相比,像聚乙烯这样的聚合物不能在某一特定的温度快速地熔融成纯净的液体。而聚合物变得越来越软,最终,变成十分粘稠的聚合物熔融体。将这种热而粘稠的聚合物熔融体进一步加热,不会转变成各种气体,但它不再是聚乙烯。
固态苯——→液态苯——→气态苯加热,℃加热,80℃
固体聚乙烯——→熔化的聚乙烯——→各种分解产物-但不是聚乙烯
加热加热
图低分子量化合物和聚合物受热后的不同行为
Another striking difference with respect to the
behavior of a polymer and that of a low molecular weight xxpound concerns the dissolution process. Let us take, for example, sodium chloride and add it slowly to s fixed quantity of water. The salt, which represents a low molecular weight xxpound, dissolves in water up to s point (called saturation point) but, thereafter, any further quantity added does not go into solution but settles at the bottom and just remains there as solid. The viscosity of the saturated salt solution is not very much different from that of water. But if we take a polymer instead,
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say, polyvinyl alcohol, and add it to a fixed quantity of water, the polymer does not go into solution immediately. The globules of polyvinyl alcohol first absorb water, swell and get distorted in shape and after a long time go into solution. Also, we can add a very large quantity of the polymer to the same quantity of water without the saturation point ever being reached. As more and more quantity of polymer is added to water, the time taken for the dissolution of the polymer
obviously increases and the mix ultimately assumes a soft, dough-like consistency. Another peculiarity is that, in water, polyvinyl alcohol never retains its original powdery nature as the excess sodium chloride does in a saturated salt solution. In conclusion, we can say that (1) the long time taken by polyvinyl alcohol for dissolution, (2) the absence of a saturation point, and (3) the increase in the viscosity are all characteristics of a typical polymer being dissolved in a solvent and these characteristics are attributed mainly to the large molecular size of the polymer. The behavior of a low molecular weight xxpound and that of a polymer on dissolution are illustrated in
发现另一种不同的聚合物行为和低分子量化合物行为是关于溶解过程。例如,让我们研究一下,将氯化钠慢慢地添加到固定量的水中。盐,代表一种低分子量化合物,在水中达到点溶解,但,此后,进一步添加盐不进入溶液中却沉到底部而保持原有的固体状态。饱和盐溶液的粘度与水的粘度不是十分不同,但是,如果我们用聚合物替代,譬如说,将聚乙烯醇添加到固定量的水中,聚合物不是马上进入到溶液中。聚乙烯醇颗粒首先吸水溶胀,发生形变,经过很长的
时间以后进入到溶液中。同样地,我们可以将大量的聚合物加入到同样量的水中,不存在饱和点。将越来越多的聚合物加入水中,认为聚合物溶解的时间明显地增加,最终呈现柔软像面团一样粘稠的混合物。另一个特点是,在水中聚乙烯醇不会像过量的氯化钠在饱和盐溶液中那样能保持其初始的粉末状态。总之,我们可以讲聚乙
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烯醇的溶解需要很长时间,不存在饱和点,粘度的增加是典型聚合物溶于溶液中的特性,这些特性主要归因于聚合物大分子的尺寸。如图说明了低分子量化合物和聚合物的溶解行为。氯化钠晶体加入到水中——→晶体进入到溶液中.溶液的粘度不是十分不同于
充分搅拌
水的粘度——→形成饱和溶液.剩余的晶体维持不溶解状态.
加入更多的晶体并搅拌
氯化钠的溶解
聚乙烯醇碎片加入到水中——→碎片开始溶胀——→碎片慢慢地进入到溶液中
允许维持现状充分搅拌
——→形成粘稠的聚合物溶液.溶液粘度十分高于水的
粘度继续搅拌
聚合物的溶解
图低分子量化合物和聚合物不同的溶解行为
——Gowariker VR, Viswanathan N V, Sreedhar J. Polymer Science. New York:
John Wiley & Sons,
UNIT 2 Chain Polymerization
第二单元链式聚合反应
Many olefinic and vinyl unsaturated xxpounds are able to form chain-0like macromolecules through elimination of the double bond, a phenomenon first recognized by Staudinger. Diolefins
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polymerize in the same manner, however, only one of the two double bonds is eliminated. Such reactions occur through the initial addition of a monomer molecule to an initiator radical or an initiator ion, by which the active state is transferred from the initiator to the added monomer. In the same way by means of a chain reaction, one monomer molecule after the other is added (20XX~20XX0 monomers per second) until
the active state is terminated through a different type of reaction. The polymerization is a chain reaction in two ways: because of the reaction kinetic and because as a reaction product one obtains a chain molecule. The length of the chain molecule is proportional to the kinetic chain length.
Staudinger第一个发现一例现象,许多烯烃和不饱和烯烃通过打开双键可以形成链式大分子。二
烯烃以同样的方式聚合,然而,仅限于两个双键中的一个。这类反应是通过单体分子首先加成到引发剂自基或引发剂离子上而进行的,靠这些反应活性中心引发剂转移到被加成的单体上。以同样的方式,借助于链式反应,单体分子一个接一个地被加成直到活性中心通过不同的反应类型而终止。聚合反应是链式反应的原因有两种:因为反应动力学和因为作为反应产物它是一种链式分子。链分子的长度与动力学链长成正比。
One can summarize the process as follow (R. is equal to the initiator radical): 链式反应可以概括为以下过程:略
One thus obtains polyvinylchloride from vinylchloride, or polystyrene from styrene, or polyethylene from ethylene, etc.
因而通过上述过程氯乙烯得到聚氯乙烯,或苯乙烯获得聚苯乙烯,或乙烯获得聚乙烯,等等。
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The length of the chain molecules, measured by means of the degree of polymerization, can be varied over a large range through selection of suitable reaction conditions. Usually, with xxmercially prepared and utilized polymers, the degree of polymerization lies in the range of 1000 to 5000, but in many cases it can be below 500 and over 10000. This should not be interpreted to mean that all molecules of a certain polymeric material consist of 500, or 1000, or 5000 monomer units. In almost all cases, the polymeric material consists of a mixture of polymer molecules of different degrees of polymerization.
借助于聚合度估算的分子链长,在一个大范围内可以通过选择适宜的反应条件被改变。通常,通过大量地制备和利用聚合物,聚合度在1000~5000范围内,但在许多情况下可低于500、高于10000。这不应该把所有聚合物材料的分子量理解为500,或1000,或5000个单体单元组成。在几乎所有的事例中,聚合物材料不同聚合度的聚合物分子的混
合物组成。
Polymerization, a chain reaction, occurs according to the same mechanism as the well-known chlorine-hydrogen reaction and the dexxposition of phosegene.
聚合反应,链式反应,依照与众所周知的氯-氢反应和光气的分解机理进行。 The initiation reaction, which is the activation process of the double bond, can be brought about by heating, irradiation, ultrasonics, or initiators. The initiation of the chain reaction can be observed most clearly with radical or ionic initiators. These are energy-rich xxpounds which can add suitable unsaturated xxpounds (monomers) and maintain the activated radical, or ionic, state so that further monomer molecules can be added in the same manner. For the individual steps of the growth reaction one needs only a relatively small activation energy and therefore through a single activation step (the 6
高分子专业英语选讲课文翻译资料
actual initiation reaction) a large number of olefin molecules are converted, as is implied by the
term “chain reaction”. Because very small amounts of the initiator bring about the formation of a large amount of polymeric material (1:1000 to 1:1000), it is possible to regard polymerization from a superficial point of view as a catalytic reaction. For this reason, the initiators used in polymerization reactions are often designated as polymerization catalysts, even though, in the strictest sense, they are not true catalysts because the polymerization initiator enters into the reaction as a real partner and can be found chemically bound in the reaction product , ,the polymer, In addition to the ionic and radical initiators there are now metal xxplex initiators (which can be obtained, for example, by the reaction of titanium tetrachloride or titanium trichloride with aluminum alkyls), which play an important role in polymerization reactions (Ziegler catalysts) ,The mechanism of their catalytic action is not yet xxpletely clear.
双键活化过程的引发剂反应,可以通过热、辐射、超声波或引发剂产生。用自基型或离子型引发剂引发链式反应可以很清楚地进行观察。这些是高能态的化合物,它们能够加成不饱和化合物并保持自基或离子活性中心以致单体可以
以同样的方式进一步加成。对于增长反应的各个步骤,每一步仅需要相当少的活化能,因此通过一步简单的活化反应即可将许多烯类单体分子转化成聚合物,这正如连锁反应这个术语的内涵那样。因为少量的引发剂引发形成大量的聚合物原料,从表面上看聚合反应很可能是催化反应。于这个原因,通常把聚合反应的引发剂看作是聚合反应的引发剂,但是,严格地讲它们不是真正意义上的催化剂,因为聚合反应的催化剂进入到反应内部而成为一部分,同时可以在反应产物,既聚合物的末端发现。此外离子引发剂和自基引发剂有的是金属络合物引发剂,Z引发剂在聚
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合反应中起到了重要作用,它们催化活动的机理还不是十分清楚。
UNIT 3 Step-Growth Polymerization
第三单元逐步聚合
Many different chemical reactions may be used to synthesize polymeric materials by step-growth polymerization. These include esterification, amidation, the formation of urethanes, aromatic substitution, etc. Polymerization proceeds by the reactions between two different functional groups, ,
hydroxyl and carboxyl groups, or isocyanate and hydroxyl groups.
许多不同的化学反应通过逐步聚合可用于合成聚合材料。这些反应包括酯化、酰胺化、氨基甲酸酯、芳香族取代物的形成等。通过反应聚合反应在两种不同的官能团,如,羟基和羧基,或异氰酸酯和羟基之间。
All step-growth polymerization fall into two groups depending on the type of monomer(s) employed. The first involves two different polyfunctional monomers in which each monomer possesses only one type of functional group. A polyfunctional monomer is one with two or more functional groups per molecule. The second involves a single monomer containing both types of functional groups. The synthesis of polyamides illustrates both groups of polymerization reactions. Thus, polyamides can be obtained from the reaction of diamines with diacids
所有的逐步聚合反应根据所使用单体的类型可分为两类。第一类涉及两种不同的官能团单体,每一种单体仅具有一种官能团。一种多官能团单体每个分子有两个或多个官能团。第二类涉及含有两类官能团的单种单体。聚酰胺的合成说明了聚合反应的两个官能团。因此聚酰胺可以二元胺和二
元酸的反应或氨基酸之间的反应得到。
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nH2N-R-NH2+nHO2C-R’-CO2H→
H-(-NH-R-NHCO-R’-CO-)n-OH+(2n-1)H2O or from the reaction of amino acids with themselves nH2R-CO2H → H-(-NH-R-CO-)n-OH+(n-1)H20
The two groups of reactions can be represented in a general manner by the equations as follows
A+B-B →–[-A-A-B-B-]-A-B→–[-A-B-]-
两种官能团之间的反应一般来说可以通过下列反应式表示反应式略
Reaction illustrates the former, while is of the latter type. 反应说明前一种形式,而反应具有后一种形式。
图逐步聚合的示意图
未反应单体;50%已反应;%已反应;(d) 100%已反应Polyesterification, whether between diol and dibasic acid or intermolecularly between hydroxy acid molecules, is an example of a step-growth polymerization process. The esterification reaction occurs anywhere in the monomer matrix where two monomer
molecules collide, and once the ester has formed, it, too, can react further by virtue of its still-reactive hydroxyl or carboxyl groups. The net effect of this is that monomer molecules are consumed rapidly without any large increase in molecular weight. Fig. illustrates this phenomenon. Assume, for example, that each square in Fig. represents a molecule of hydroxy acid. After the initial dimmer molecules from (b), half the monomer molecules have
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高分子专业英语选讲课文翻译资料 A 高分子化学和高分子物理 UNIT 1 What are Polymer 第一单元什么是高聚物?
What are polymers For one thing, they are xxplex and giant molecules and are different from low molecular weight xxpounds like, say, xxmon salt. To contrast the difference, the molecular weight of xxmon salt is only , while that of a polymer can be as high as several hundred thousand, even more than thousand thousands. These big molecules or ‘macro-molecules’are made up of much smaller molecules, can be of one or more chemical xxpounds. To illustrate, imagine that
a set of rings has the same size and is made of the same material. When these things are interlinked, the chain formed can be considered as representing a polymer from molecules of the same xxpound. Alternatively, individual rings could be of different sizes and materials, and interlinked to represent a polymer from molecules of different xxpounds.
什么是高聚物?首先,他们是合成物和大分子,而且不同于低分子化合物,譬如说普通的盐。与低分子化合物不同的是,普通盐的分子量仅仅是,而高聚物的分子量高于105,甚至大于106。这些大分子或“高分子”许多小分子组成。小分子相互结合形成大分子,大分子能够是一种或多种化合物。举例说明,想象一组大小相同并相同的材料制成的环。当这些环相互连接起来,可以把形成的链看成是具有同种分子量化合物组成的高聚物。另一方面,独特的环可以大小不同、材料不同,相连接后形成具有不同分子量化合物组成的聚合物。
This interlinking of many units has given the polymer its name, poly meaning ‘many’ and mer meaning ‘part’ (in Greek). As an example, a gaseous xxpound called butadiene, with a molecular
高分子专业英语选讲课文翻译资料
weight of 54, xxbines nearly 4000 times and gives a polymer known as polybutadiene (a synthetic rubber) with about 200 000molecular weight. The low molecular weight xxpounds from which the polymers form are known as monomers. The picture is simply as follows: 许多单元相连接给予了聚合物一个名称,poly意味着“多、聚、重复”,mer意味着“链节、基体”。例如:称为丁二烯的气态化合物,分子量为54,化合将近4000次,得到分子量大约为20XX00被称作聚丁二烯的高聚物。形成高聚物的低分子化合物称为单体。下面简单地描述一下形成过程:
butadiene + butadiene + + butadiene--→polybutadiene
(4 000 time)
丁二烯+丁二烯+…+丁二烯——→聚丁二烯
One can thus see how a substance (monomer) with as small a molecule weight as 54 grow to bexxe a giant molecule (polymer) of (54×4 000≈)200 000 molecular weight. It is essentially the ‘giantness’ of the size of the polymer molecule that makes its behavior different from that of a xxmonly known chemical xxpound
such as benzene. Solid benzene, for instance, melts to bexxe liquid benzene at ℃ and , on further heating, boils into gaseous benzene. As against this well-defined behavior of a simple chemical xxpound, a polymer like polyethylene does not melt sharply at one particular temperature into clean liquid. Instead, it bexxes increasingly softer and,
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ultimately, turns into a very viscous, tacky molten mass. Further heating of this hot, viscous, molten polymer does convert it into various gases but it is no longer polyethylene. (Fig. ) .
因而能够看到分子量仅为54的小分子物质如何逐渐形成分子量为20XX00的大分子。实质上,正是于聚合物的巨大的分子尺寸才使其性能不同于象苯这样的一般化合物。例如,固态苯,在℃熔融成液态苯,进一步加热,煮沸成气态苯。与这类简单化合物明确的行为相比,像聚乙烯这样的聚合物不能在某一特定的温度快速地熔融成纯净的液体。而聚合物变得越来越软,最终,变成十分粘稠的聚合物熔融体。将这种热而粘稠的聚合物熔融体进一步加热,不会转变成各种气体,但它不再是聚乙烯。
固态苯——→液态苯——→气态苯加热,℃加热,80℃
固体聚乙烯——→熔化的聚乙烯——→各种分解产物-但不是聚乙烯
加热加热
图低分子量化合物和聚合物受热后的不同行为
Another striking difference with respect to the behavior of a polymer and that of a low molecular weight xxpound concerns the dissolution process. Let us take, for example, sodium chloride and add it slowly to s fixed quantity of water. The salt, which represents a low molecular weight xxpound, dissolves in water up to s point (called saturation point) but, thereafter, any further quantity added does not go into solution but settles at the bottom and just remains there as solid. The viscosity of the saturated salt solution is not very much different from that of water. But if we take a polymer instead,
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say, polyvinyl alcohol, and add it to a fixed quantity of water, the polymer does not go into solution
城市学院英语课文翻 译
Don't Wait Until Death Does Its Part We have but one body. It must last a lifetime. Without it, life ends, and we are done and finished. But do we treat our body fairly, lovingly, like prized possessions? Do we appreciate our body's nonstop efforts to function smoothly? My body asks for little: water to keep hydrated; food for nutrients, energy, and strong bones; rest when I'm tired or sick; and play to lift my spirits. Its ability to self-repair and respond to good care is incredible. But until recently, I have abused my body with excesses of all kinds. Not only did I take its resiliency for granted, I was annoyed when a physical problem, such as a cold or injury, kept me from doing what I want. Moreover, I was harshly critical when it failed to conform to standards of beauty in the media. My overeating, lazy lifestyle, and excessive work had a negative impact on my life, though not fatal. I've also seen friends and family members destroy their body through drugs, alcoholism, or workaholism. For years I had good intentions to change, but I didn't follow through. I could see my future: increased medical expenses, exhausted senses, premature death. Once I understand that it is in my own self-interest to take care of it, I'm struggling to develop a positive relationship with my body. Evidently, I'm not the only one with this awareness now. I begin to make more constructive choices. Instead of asking the question, “What do I want?” I ask, “What does my body need?” And then I respond acc ordingly. Positive actions — exercising, eating mindfully, getting enough rest and water, limiting my work hours, and scheduling recreation — have gradually become regular habits rather than disciplined efforts. After all, each of us gets only one body. So don't wait until death does its part. Appreciate our body and treat it lovingly. It will reward us with a longer, healthier and happier life.
A 高分子化学和高分子物理 UNIT 1 What are Polymer? 第一单元什么是高聚物? What are polymers? For one thing, they are complex and giant molecules and are different from low molecular weight compounds like, say, common salt. To contrast the difference, the molecular weight of common salt is only 58.5, while that of a polymer can be as high as several hundred thousand, even more than thousand thousands. These big molecules or ‘macro-molecules’are made up of much smaller molecules, can be of one or more chemical compounds. To illustrate, imagine that a set of rings has the same size and is made of the same material. When these things are interlinked, the chain formed can be considered as representing a polymer from molecules of the same compound. Alternatively, individual rings could be of different sizes and materials, and interlinked to represent a polymer from molecules of different compounds. 什么是高聚物?首先,他们是合成物和大分子,而且不同于低分子化合物,譬如说普通的盐。与低分子化合物不同的是,普通盐的分子量仅仅是58.5,而高聚物的分子量高于105,甚至大于106。这些大分子或“高分子”由许多小分子组成。小分子相互结合形成大分子,大分子能够是一种或多种化合物。举例说明,想象一组大小相同并由相同的材料制成的环。当这些环相互连接起来,可以把形成的链看成是具有同种分子量化合物组成的高聚物。另一方面,独特的环可以大小不同、材料不同,相连接后形成具有不同分子量化合物组成的聚合物。 This interlinking of many units has given the polymer its name, poly meaning ‘many’and mer meaning ‘part’(in Greek). As an example, a gaseous compound called butadiene, with a molecular weight of 54, combines nearly 4000 times and gives a polymer known as polybutadiene (a synthetic rubber) with about 200 000molecular weight. The low molecular weight compounds from which the polymers form are known as monomers. The picture is simply as follows: 许多单元相连接给予了聚合物一个名称,poly意味着“多、聚、重复”,mer意味着“链节、基体”(希腊语中)。例如:称为丁二烯的气态化合物,分子量为54,化合将近4000次,得到分子量大约为200000被称作聚丁二烯(合成橡胶)的高聚物。形成高聚物的低分子化合物称为单体。下面简单地描述一下形成过程: butadiene + butadiene + ???+ butadiene--→polybutadiene (4 000 time) 丁二烯+丁二烯+…+丁二烯——→聚丁二烯 (4000次) One can thus see how a substance (monomer) with as small a molecule weight as 54 grow to become a giant molecule (polymer) of (54×4 000≈)200 000 molecular weight. It is essentially the ‘giantness’of the size of the polymer molecule that makes its behavior different from that of a commonly known chemical compound such as benzene. Solid benzene, for instance, melts
翻译 Unit11 1、他暗示John是肇事者的企图是徒劳的。(insinuate,futile)暗示,无用的;无效的 His attempt at insinuating that John was the culprit turned out to be futile. 2、当他未能完成期望他做的事时,他很善于临时找个借口来为自己开脱。(improvise)临时做 He is very clever at improvising excuses when he fails to do what is expected of him. 3、他此行去西藏可以满足他想参观布达拉宫的愿望了。(gratify)使满足;使满意,使高兴 His trip to Tibet will gratify his desire to see Potala. (the Potala Palace) 4、这个公司拥有雄厚的人力资源。(command)命令,指挥;控制 This corporation commands excellent/rich/abundant human resources. 5、另外想个办法去款待你的客人。不要老是请他们看影视光碟。(alternative)二中择一;供替代的选择Think of an alternative way of entertaining your guests. Don’t always show them VCDs. 6、沉溺于胡思乱想和心血来潮是有害的。(caprice)任性,反复无常;随想曲 It is harmful to indulge in whims and caprices. 7、不属于你的东西不要作非分之想。(lay one’s hands on,be entitled to)2有权;有…的资格 Try not to lay your hands on anything that you are not entitled to. 8、他没有来参加竞赛。很可能他把这件事全部忘记了。(it may well be that)可能会是 He did not come to the competition. It may well be that he had forgotten all about it. Unit10 1、他奇特的行为与对良好举止的一般观念背道而驰。(run counter to)违反;与…背道而驰 His peculiar behavior runs counter to the popular concept of good conduct. 2、相对论对现代科学产生了巨大影响。(impact)对…造成影响; 产生影响 The theory of relativity made a great impact on modern science. 3、任何人都没有权利嘲笑残疾人的不利条件。(deride)vt. 嘲笑;嘲弄 No one has the right to deride the disadvantages of handicapped people. 4、在她毕业典礼哪天,Judy的叔叔婶婶以丰盛的晚餐来款待她。(sumptuous)华丽的,豪华的;奢侈的 On her graduation day, Judy was treated to a sumptuous dinner by her uncle and aunt. 5、关于他过去在公司的经历,没有什么人有不满。(with respect to)关于,至于;就…而言 With respect to his past record in the firm, no one has anything to complain about. 6、她深深地陷入反对校董会的密谋之中。(inextricably)adv. 逃不掉地;解不开地;解决不了地He is inextricably involved in the plot against the school board. 7、我年迈的叔祖母很不习惯那些充斥市场的一次性物品。(disposable)用完即可丢弃的 My aged great-aunt is not used to the disposable goods which flood the market today. 8、他在考试作弊被发现后,他的名字马上从应试者的名单上删去了。(eliminate)vt. 消除;排除His name was immediately eliminated from the list of candidates after he was caught cheating in the exam. Unit 9 1、如果对这器械有什么不清楚的地方,你可以写信到我们总公司去询问。(address) If there is anything you are not clear about the device, address your inquiry to your head office. 2、在执行计划之前,我们最好把它的每一个方面仔细考虑,看看是否切实可行。(scrutinize)vt. 详细检查;细看 Before we put the new plan into practice, we had bitter scrutinize every aspect of it to make sure that it is practicable.
Lesson 1 力学的基本概念 1、词汇: statics [st?tiks] 静力学;dynamics动力学;constraint约束;magnetic [m?ɡ'netik]有磁性的;external [eks't?:nl] 外面的, 外部的;meshing啮合;follower从动件;magnitude ['m?ɡnitju:d] 大小;intensity强度,应力;non-coincident [k?u'insid?nt]不重合;parallel ['p?r?lel]平行;intuitive 直观的;substance物质;proportional [pr?'p?:??n?l]比例的;resist抵抗,对抗;celestial [si'lestj?l]天空的;product乘积;particle质点;elastic [i'l?stik]弹性;deformed变形的;strain拉力;uniform全都相同的;velocity[vi'l?siti]速度;scalar['skeil?]标量;vector['vekt?]矢量;displacement代替;momentum [m?u'ment?m]动量; 2、词组 make up of由……组成;if not要不,不然;even through即使,纵然; Lesson 2 力和力的作用效果 1、词汇: machine 机器;mechanism机构;movable活动的;given 规定的,给定的,已知的;perform执行;application 施用;produce引起,导致;stress压力;applied施加的;individual单独的;muscular ['m?skjul?]]力臂;gravity[ɡr?vti]重力;stretch伸展,拉紧,延伸;tensile[tensail]拉力;tension张力,拉力;squeeze挤;compressive 有压力的,压缩的;torsional扭转的;torque转矩;twist扭,转动;molecule [m likju:l]分子的;slide滑动; 滑行;slip滑,溜;one another 互相;shear剪切;independently独立地,自立地;beam梁;compress压;revolve (使)旋转;exert [iɡ'z?:t]用力,尽力,运用,发挥,施加;principle原则, 原理,准则,规范;spin使…旋转;screw螺丝钉;thread螺纹; 2、词组 a number of 许多;deal with 涉及,处理;result from由什么引起;prevent from阻止,防止;tends to 朝某个方向;in combination结合;fly apart飞散; 3、译文: 任何机器或机构的研究表明每一种机构都是由许多可动的零件组成。这些零件从规定的运动转变到期望的运动。另一方面,这些机器完成工作。当由施力引起的运动时,机器就开始工作了。所以,力和机器的研究涉及在一个物体上的力和力的作用效果。 力是推力或者拉力。力的作用效果要么是改变物体的形状或者运动,要么阻止其他的力发生改变。每一种
Unit 3 Out of Step Bill Bryson 1 After living in England for 20 years, my wife and I decided to move back to the United States. We wanted to live in a town small enough that we could walk to the business district, and settled on Hanover, N.H., a typical New England town—pleasant, sedate and compact. It has a broad central green surrounded by the venerable buildings of Dartmouth College, an old-fashioned Main Street and leafy residential neighborhoods. 2 It is, in short, an agreeable, easy place to go about one’ s business on foot, and ye far as I can tell, virtually no one does. 3 Nearly every day, I walk to the post office or library or bookstore, and sometimes, if I am feeling particu larly debonair, I stop at Rosey Jekes Caféa cappuccino. Occasionally, in the evenings, my wife and I stroll up to the Nugget Theatre for a movie or to Murphy’ s on the Green for a beer, I wouldn’ t dream of going to any of these places by car. People ha ve gotten used to my eccentric behavior, but in the early days acquaintances would often pull up to the curb and ask if I wanted a ride. 4“ I’ m going your way,” they would insist when I politely declined. no bother.”
高分子专业英语课文翻译 高分子专业英语选讲课文翻译资料 A 高分子化学和高分子物理 UNIT 1 What are Polymer? 第一单元什么是高聚物, What are polymers? For one thing, they are complex and giant molecules and 什么是高聚物, 首先,他们是合成物和大分子,而且不同于低分子化合物,譬are different from low molecular weight compounds like, say, common salt. To 如说普通的盐。 contrast the difference, the molecular weight of common salt is only 58.5, while 与低分子化合物不同的是,普通盐的分子量仅仅是58.5, that of a polymer can be as high as several hundred thousand, even more than thousand 而高聚物的分子量高于105,甚至大于106。 thousands. These big molecules or ‘macro-molecules’ are made up of much smaller 这些大分子或“高分子”由许多小分子组成, 小分子相互结合形成大分子,molecules, can be of one or more chemical compounds. To illustrate, imagine that 大分子能够是一种或多种化合物。举例说明, a set of rings has the same size and is made of the same material. When these things 想象一组大小相同并由相同的材料制成的环。当这些环相互连接are
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。一特定形式的适用于大范围的工程材料至少工程材料受载荷的大部分的弹性, 产生正比于负载的变形。由于载荷正比于载荷所产生的压力并且变形正比于应变, 这也说明,当材料是弹性的时候, 应力与应变成正比。因此胡克定律陈述, 应力正比于应变。 这定律服从于大部分铁合金在特定的范围内, 甚至以其合理的准确性可以假定适用于其他工程材料比如混凝土,木材,非铁合金。 当一个材料是弹性的时候,当载荷消除之后,任何负载所产生的变形可以完全恢复,没有永久的变形。
Unit 1 Text A Howard Gardner, a professor of education at Harvard University, reflects on a visit to China and gives his thoughts on different approaches to learning in China and the West. 哈佛大学教育学教授霍华德·加德纳回忆其中国之行,阐述他对中西方不同的学习方式的看法。 Learning, Chinese-Style Howard Gardner 1 For a month in the spring of 1987, my wife Ellen and I lived in the bustling eastern Chinese city of Nanjing with our 18-month-old son Benjamin while studying arts education in Chinese kindergartens and elementary schools. But one of the most telling lessons Ellen and I got in the difference between Chinese and American ideas of education came not in the classroom but in the lobby of the Jinling Hotel where we stayed in Nanjing. 中国式的学习风格 霍华德·加德纳 1987年春,我和妻子埃伦带着我们18个月的儿子本杰明在繁忙的中国东部城市南京住了一个月,同时考察中国幼儿园和小学的艺术教育情况。然而,我和埃伦获得的有关中美教育观念差异的最难忘的体验并非来自课堂,而是来自我们在南京期间寓居的金陵饭店的大堂。 2 The key to our room was attached to a large plastic block with the room number on it. When leaving the hotel, a guest was encouraged to turn in the key, either by handing it to an attendant or by dropping it through a slot into a box. Because the key slot was narrow, the key had to be positioned carefully to fit into it. 我们的房门钥匙系在一块标有房间号的大塑料板上。酒店鼓励客人外出时留下钥匙,可以交给服务员,也可以从一个槽口塞入钥匙箱。由于口子狭小,你得留神将钥匙放准位置才塞得进去。 3 Benjamin loved to carry the key around, shaking it vigorously. He also liked to try to place it into the slot. Because of his tender age and incomplete understanding of the need to position the key just so, he would usually fail. Benjamin was not bothered in the least. He probably got as much pleasure out of the sounds the key made as he did those few times when the key actually found its way into the slot. 本杰明爱拿着钥匙走来走去,边走边用力摇晃着。他还喜欢试着把钥匙往槽口里塞。由于他还年幼,不太明白得把钥匙放准位置才成,因此总塞不进去。本杰明一点也不在意。他从钥匙声响中得到的乐趣大概跟他偶尔把钥匙成功地塞进槽口而获得的乐趣一样多。 4 Now both Ellen and I were perfectly happy to allow Benjamin to bang the key
UNIT 1 What Are Polymers? 第一单元什么是高聚物? 什么是高聚物?首先,他们是络合物和大分子,而且不同于低分子化合物,譬如说普通的盐。与低分子化合物不同的是,普通盐的分子量仅仅是58.5,而高聚物的分子量高于105,甚至大于106。这些大分子或“高分子”由许多小分子组成。小分子相互结合形成大分子,大分子能够是一种或多种化合物。举例说明,想象一组大小相同并由相同的材料制成的环。当这些环相互连接起来,可以把形成的链看成是具有同种(分子量)化合物组成的高聚物。另一方面,独立的环可以大小不同、材料不同,相连接后形成具有不同(分子量)化合物组成的聚合物。 许多单元相连接给予了聚合物一个名称,poly意味着“多、聚、重复”,mer意味着“链节、基体”(希腊语中)。例如:称为丁二烯的气态化合物,分子量为54,化合将近4000次,得到分子量大约为200000被称作聚丁二烯(合成橡胶)的高聚物。形成高聚物的低分子化合物称为单体。下面简单地描述一下形成过程: 丁二烯+丁二烯+…+丁二烯——→聚丁二烯 (4000次) 因而能够看到分子量仅为54的小分子物质(单体)如何逐渐形成分子量为200000的大分子(高聚物)。实质上,正是由于聚合物的巨大的分子尺寸才使其性能不同于像苯这样的一般化合物(的性能)。1例如,固态苯,在5.5℃熔融成液态苯,进一步加热,煮沸成气态苯。与这类简单化合物明确的行为相比,像聚乙烯这样的聚合物不能在某一特定的温度快速地熔融成纯净的液体。而聚合物变得越来越软,最终,变成十分粘稠的聚合物熔融体。将这种热而粘稠的聚合物熔融体进一步加热,不会转变成各种气体,但它不再是聚乙烯(如图1.1)。 固态苯——→液态苯——→气态苯 加热,5.5℃加热,80℃ 固体聚乙烯——→熔化的聚乙烯——→各种分解产物-但不是聚乙烯 加热加热 图1.1 低分子量化合物(苯)和聚合物(聚乙烯)受热后的不同行为发现另一种不同的聚合物行为和低分子量化合物行为是关于溶解过程。例如,让我们研究一下,将氯化钠慢慢地添加到固定量的水中。盐,代表一种低分子量化合物,在水中达到点(叫饱和点)溶解,但,此后,进一步添加盐不进入溶液中却沉到底部而保持原有的固体状态。饱和盐溶液的粘度与水的粘度不是十分不同,但是,如果我们用聚合物替代,譬如说,将聚乙烯醇添加到固定量的水中,聚合物不是马上进入到溶液中。聚乙烯醇颗粒首先吸水溶胀,发生形变,经过很长的时间以后,(聚乙烯醇分子)进入到溶液中。2同样地,我们可以将大量的聚合物加入到同样量的水中,不存在饱和点。将越来越多的聚合物加入水中,认为聚合物溶解的时间明显地增加,最终呈现柔软像面团一样粘稠的混合物。另一个特点是,在水中聚乙烯醇不会像过量的氯化钠在饱和盐溶液中那样能保持其初始的粉末状态。3总之,我们可以讲(1)聚乙烯醇的溶解需要很长时间,(2)不存在饱和点,(3)粘度的增加是典 型聚合物溶于溶液中的特性,这些特性主要归因于聚合物大分子的尺寸。 如图1.2说明了低分子量化合物和聚合物的溶解行为。 氯化钠晶体加入到水中→晶体进入到溶液中.溶液的粘度不是十分不同于充分搅拌 水的粘度→形成饱和溶液.剩余的晶体维持不溶解状态.加入更多的晶体并搅拌氯化钠的溶 解 聚乙烯醇碎片加入到水中→碎片开始溶胀→碎片慢慢地进入到溶液中允许维持现状 充分搅拌→形成粘稠的聚合物溶液.溶液粘度十分高于水的粘度继续搅拌聚合物的溶解
机械制造专业英语文章 篇一:机械专业英语文章中英文对照 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。 Metals and Metal Alloys 金属和金属合金 Metals are elements that generally have good electrical and thermal conductivity. Many metals have high strength, high stiffness, and have good ductility. 金属就是通常具有良好导电性和导热性的元素。许多金属具有高强度、高硬度以及良好的延展性。 Some metals, such as iron, cobalt and nickel, are magnetic. At low temperatures, some metals and intermetallic compounds become superconductors. 某些金属能被磁化,例如铁、钴和镍。在极低的温度下,某些金属和金属化合物能转变成超导体。 What is the difference between an alloy and a pure metal? Pure metals are elements which come from a particular area of the periodic table. Examples of pure metals include copper in electrical wires and aluminum in cooking foil and beverage cans. 合金与纯金属的区别是什么?纯金属是在元素周期表中占据特定位置的元素。 例如电线中的铜和制造烹饪箔及饮料罐的铝。 Alloys contain more than one metallic element. Their properties can be changed by changing the elements present in the alloy. Examples of metal alloys include stainless steel which is an alloy of iron, nickel, and chromium; and gold jewelry which usually contains an alloy of gold
unit1 1.Not all polymers are built up from bonding together a single kind of repeating unit. At the other extreme ,protein molecules are polyamides in which n amino acide repeat units are bonded together. Although we might still call n the degree of polymerization in this case, it is less usefull,since an amino acid unit might be any one of some 20-odd molecules that are found in proteins. In this case the molecular weight itself,rather than the degree of the polymerization ,is generally used to describe the molecule. When the actual content of individual amino acids is known,it is their sequence that is of special interest to biochemists and molecular biologists.并不是所有的聚合物都是由一个重复单元链接在一起而形成的。在另一个极端的情形中,蛋白质分子是由n个氨基酸重复单元链接在一起形成的聚酰胺。尽管在这个例子中,我们也许仍然把n称为聚合度,但是没有意义,因为一个氨基酸单元也许是在蛋白质中找到的20多个分子中的任意一个。在这种情况下,一般是分子量本身而不是聚合度被用来描述这个分子。当知道了特定的氨基酸分子的实际含量,它们的序列正是生物化学家和分子生物学家特别感兴趣的地方。 1,题目:Another striking ...答案:.that quantity low saturation bottom much absorb 2. 乙烯分子带有一个双键,为一种烯烃,它可以通过连锁聚合大量地制造聚乙烯,目前,聚乙烯已经广泛应用于许多技术领域和人们的日常生活中,成为一种不可缺少的材料。 Ethylene molecule with a double bond, as a kind of olefins, it can make chain polymerization polyethylene, at present, polyethylene has been widely used in many fields of technology and People's Daily life, become a kind of indispensable materials. Unit3 1 The polymerization rate may be experimentally followed by measuring the changes in any of several properties of the system such as density,refractive index,viscosity, or light absorption. Density measurements are among the most accurate and sensitive of the techniques. The density increases by 20-25 percent on polymerization for many monomers. In actual practice the volume of the polymerizing system is measured by carrying out the reaction in a dilatometer. This is specially constructed vessel with a capillary tube which allows a highly accurate measurement of small volume changes. It is not uncommon to be able to detect a few hundredths of a percent polymerization by the dilatometer technique. 聚合速率在实验上可以通过测定体系的任一性质的变化而确定,如密度、折射率、黏度、或者吸光性能。密度的测量是这些技术中最准确最敏感的。对许多单体的聚合来说,密度增加了20%-25%。在实际操作中,聚合体系的体积是通过在膨胀计中进行反应测定的。它被专门设计构造了毛细导管,在里面可以对微小体积变化进行高精确度测量。通过膨胀计技术探测聚合过程中万分之几的变化是很常见的。 Unti4 2 合成聚合物在各个领域中起着与日俱增的重要作用,聚合物通常是由单体通过加成聚合与缩合聚合制成的。就世界上的消耗量而论,聚烯烃和乙烯基聚合物居领先地位,聚乙烯、聚丙烯等属聚烯烃,而聚氯乙烯、聚苯乙烯等则为乙烯基聚合物。聚合物可广泛地用作塑料、橡胶、纤维、涂料、粘合剂等The synthetic polymers play an increasingly