化学工艺英语

发布时间：2024-04-26 23:42:54　影响了：人

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化学工艺英语篇一：《化学工程与工艺专业英语》翻译

Unit 1Chemical Industry 化学工业

1．化学工业的起源

尽管化学品的使用可以追溯到古代文明时代，我们所谓的现代化学工业的发展却是非常近代（才开始的）。可以认为它起源于工业革命其间，大约在1800年，并发展成为为其它工业部门提供化学原料的产业。比如制肥皂所用的碱，棉布生产所用的漂白粉，玻璃制造业所用的硅及Na2CO3. 我们会注意到所有这些都是无机物。有机化学工业的开始是在十九世纪六十年代以William Hey Perkin 发现第一种合成染料—苯胺紫并加以开发利用为标志的。20世纪初，德国花费大量资金用于实用化学方面的重点研究，到1914年，德国的化学工业在世界化学产品市场上占有75%的份额。这要归因于新染料的发现以及硫酸的接触法生产和氨的哈伯生产工艺的发展。而后者需要较大的技术突破使得化学反应第一次可以在非常高的压力条件下进行。这方面所取得的成绩对德国很有帮助。特别是由于1914年第一次世界大仗的爆发，对以氮为基础的化合物的需求飞速增长。这种深刻的改变一直持续到战后（1918-1939）。

1940年以来，化学工业一直以引人注目的速度飞速发展。尽管这种发展的速度近年来已大大减慢。化学工业的发展由于1950年以来石油化学领域的研究和开发大部分在有机化学方面取得。石油化工在60年代和70年代的迅猛发展主要是由于人们对于合成高聚物如聚乙烯、聚丙烯、尼龙、聚脂和环氧树脂的需求巨大增加。

今天的化学工业已经是制造业中有着许多分支的部门，并且在制造业中起着核心的作用。它生产了数千种不同的化学产品，而人们通常只接触到终端产品或消费品。这些产品被购买是因为他们具有某些性质适合（人们）的一些特别的用途，例如，用于盆的不粘涂层或一种杀虫剂。这些化学产品归根到底是由于它们能产生的作用而被购买的。

化学工业的定义

在本世纪初，要定义什么是化学工业是不太困难的，因为那时所生产的化学品是很有限的，而且是非常清楚的化学品，例如，烧碱，硫酸。然而现在有数千种化学产品被生产，从一些原料物质像用于制备许多的半成品的石油，到可以直接作为消费品或很容易转化为消费品的商品。困难在于如何决定在一些特殊的生产过程中哪一个环节不再属于化学工业的活动范畴。举一个特殊的例子来描述一下这种困境。乳剂漆含有聚氯乙烯/聚醋酸乙烯。显然，氯乙烯（或醋酸乙烯）的合成以及聚合是化学活动。然而，如果这种漆，包括高聚物，它的配制和混合是由一家制造配料的跨国化学公司完成的话，那它仍然是属于化学工业呢还是应当归属于装饰工业中去呢？

因此，很明显，由于化学工业经营的种类很多并在很多领域与其它工业有密切的联系，所以不能对它下一个简单的定义。相反的每一个收集和出版制造工业统计数据的官方机构都会对如何届定哪一类操作为化学工业有自己的定义。当比较来自不同途径的统计资料时，记住这点是很重要的。

对化学工业的需要

化学工业涉及到原材料的转化，如石油首先转化为化学中间体，然后转化为数量众多的其它化学产品。这些产品再被用来生产消费品，这些消费品可以使我们的生活更为舒适或者作药物维持人类的健康或生命。在生产过程的每一个阶段，都有价值加到产品上面，只要这些附加的价值超过原材料和加工成本之和，这个加工就产生了利润。而这正是化学工业要达到的目的。

在这样的一本教科书中提出：“我们需要化学工业吗？”这样一个问题是不是有点奇怪呢？然而，先回答下面几个问题将给我们提供一些信息：（1）化学工业的活动范围，（2）化学工业对我们日常生活的影响，

（3）社会对化学工业的需求有多大。在回答这些问题的时候我们的思路将要考虑化学工业在满足和改善我们的主要需求方面所做的贡献。是些什么需求呢？很显然，食物和健康是放在第一位的。其它我们要考虑的按顺序是衣物、住所、休闲和旅行。

(1)食物。化学工业对粮食生产所做的巨大贡献至少有三个方面。第一，提供大量可以获得的肥料以补充由于密集耕作被农作物生长时所带走的营养成分。（主要是氮、磷和钾）。第二，生产农作物保护产品，如杀虫剂，它可以显著减少害虫所消耗的粮食数量。第三，生产兽药保护家禽免遭疾病或其它感染的侵害。

（2）健康。我们都很了解化学工业中制药这一块在维护我们的身体健康甚至延长寿命方面所做出的巨大贡献，例如，用抗生素治疗细菌感染，用β-抗血栓降低血压。

衣物。在传统的衣服面料上，现代合成纤维性质的改善也是非常显著的。用聚脂如涤纶或聚酰胺如尼龙所制作的T恤、上衣、衬衫抗皱、可机洗，晒干自挺或免烫，也比天然面料便宜。

与此同时，现代合成染料开发和染色技术的改善使得时装设计师们有大量的色彩可以利用。的确他们几乎利用了可见光谱中所有的色调和色素。事实上如果某种颜色没有现成的，只要这种产品确有市场，就可以很容易地通过对现有的色彩进行结构调整而获得。

这一领域中另一些重要进展是不褪色，即在洗涤衣物时染料不会被洗掉。

（4）住所，休闲和旅游。讲到住所方面现代合成高聚物的贡献是巨大的。塑料正在取代像木材一类的传统建筑材料，因为它们更轻，免维护（即它们可以抵抗风化，不需油漆）。另一些高聚物，比如，脲甲醛和聚脲，是非常重要的绝缘材料可以减少热量损失因而减少能量损耗。

塑料和高聚物的应用对休闲活动有很重要的影响，从体育跑道的全天候人造篷顶，足球和网球的经纬线，到球拍的尼龙线还有高尔夫球的元件，还有制造足球的合成材料。

多年来化学工业对旅游方面所作的贡献也有很大的提高。一些添加剂如抗氧化剂的开发和发动机油粘度指数改进使汽车日产维修期限从3000英里延长到6000英里再到12000英里。研发工作还改进了润滑油和油脂的性能，并得到了更好的刹车油。塑料和高聚物对整个汽车业的贡献的比例是惊人的，源于这些材料—挡板，轮胎，坐垫和涂层等等—超过40%。

很显然简单地看一下化学工业在满足我们的主要需求方面所做的贡献就可以知道，没有化工产品人类社会的生活将会多么困难。事实上，一个国家的发展水平可以通过其化学工业的生产水平和精细程度来加以判断。

化学工业的研究和开发。

发达国家化学工业飞速发展的一个重要原因就是它在研究和开发方面的投入和投资。通常是销售收入的5%，而研究密集型分支如制药，投入则加倍。要强调这里我们所提出的百分数不是指利润而是指销售收入，也就是说全部回收的钱，其中包括要付出原材料费，企业管理费，员工工资等等。过去这笔巨大的投资支付得很好，使得许多有用的和有价值的产品被投放市场，包括一些合成高聚物如尼龙和聚脂，药品和杀虫剂。尽管近年来进入市场的新产品大为减少，而且在衰退时期研究部门通常是最先被裁减的部门，在研究和开发方面的投资仍然保持在较高的水平。

化学工业是高技术工业，它需要利用电子学和工程学的最新成果。计算机被广泛应用，从化工厂的自动控制，到新化合物结构的分子模拟，再到实验室分析仪器的控制。

一个制造厂的生产量很不一样，精细化工领域每年只有几吨，而巨型企业如化肥厂和石油化工厂有可能高达500,000吨。后者需要巨大的资金投入，因为一个这样规模的工厂要花费2亿5千万美元，再加上自动控制设备的普遍应用，就不难解释为什么化工厂是资金密集型企业而不是劳动力密集型企业。

大部分化学公司是真正的跨国公司，他们在世界上的许多国家进行销售和开发市场，他们在许多国家都有制造厂。这种国际间的合作理念，或全球一体化，是化学工业中发展的趋势。大公司通过在别的国家建造制造厂或者是收购已有的工厂进行扩张。

Unit 4 Sources of chemicals化学物质的来源

化学物质的数量多得惊人，其差异很大：所知道的化学物质的数量就达上千万种。如此的数量与理论上可能形成的含碳化合物的数量相比，相形见绌。含碳化合物的数量之大是耦合的结果：即相对较强的碳碳共价键的碳原子长链和异构体的形成。大部分这些化合物只是满足实验室好奇心或学术兴趣。然而，其他剩余的达几千种，是商业和实践兴趣。因此，可以预料到这些化学物质的来源很广。虽然对无机化学品如此，但是奇怪的是，大多数有机化学品来源于一种资源，即原油（石油）。

1. 无机化学品

因为“无机化学品”这个词（术语）涉及到（cover，包括、涵盖）的是除碳以外所有元素构成的化合物。其来源的多样性并不很大（见表1-1）。一些较重要的来源是金属矿（包括重要的金属铁和铝）以及盐和海水（用于生产氯、钠、氢氧化钠和碳酸钠）。在这些情况下，至少两种不同的元素化合以一种稳定的化合物在一起。因此，如果要得到单个元素（也就是金属），那么提取过程除了纯物理的分离方法以外，还必

须涉及到化学处理（过程）。金属矿或无机矿很少以纯物质的形式存在，因此，处理过程的第一步通常是：（将无机矿中）从不要的固体如粘土或沙石中分离出来。固体筛分后经压碎和研磨，利用颗粒尺寸差异可以完成一些物理分离。下一步骤则取决于所需矿物的本质及其特征。例如，铁矿常在磁分离器利用他们的磁性加以分离。泡沫浮选是另一种广泛应用的分离技术。在该技术中，所需要的矿物，以细小颗粒形式存在，借助被水溶液润湿能力的差异而与其他矿物加以分离。常加入表面活性剂（抗润湿剂），这些典型的分子，一头为非极性部分（如长碳氢链），另一头为极性部分（如-NH2）。该极性基团与矿物相吸，形成不牢固的键；而碳氢基团与水相斥而阻止矿物被润湿，因而矿物能浮选。相反，其他固体物质很容易被润湿而沉在水溶液中。搅拌溶液或液体中鼓泡以产生泡沫能大大促进表面活性剂包裹的矿物的漂浮，这些矿物从容器中溢出到收集容器中，在收集容器，矿物得到回收。显然，该过程成功的关键在于，为所处理矿物选择一种高选择的特定的表面活性剂。

2 有机化合物

相比于无机化学品来自于众多不同的资源（这一点我们已经明白了），商业上的一些重要的有机化合物基本上来源单一。如今，所有有机化合物的99%以上，可以通过石化工艺过程从原油（石油）和天然气得到。这是一种有趣的情形— — 该情形一直在改变，而且将来也会变化，因为从技术上讲，相同的化学品可以从其他原料得到。尤其是脂肪族化合物，可以通过由碳水化合物的发酵所得的乙醇加以生产，另一方面，芳香族化合物可以从煤焦油中分离得到。煤焦油是煤炭化工过程的副产物。动植物油脂，是为数不多的脂肪族化合物的特定的资源，这些脂肪族化合物包括长链脂肪酸（如正十八酸）和长链醇（如正十二烷醇）。

化石燃料（即石油、天然气和煤）的形成要花上百万年，一旦用掉就不能被替换，因此，它们称之为不可再生的资源。这与来自于植物的碳水化合物恰恰相反，碳水化合物能够较快被更新。一种较为普遍应用的资源为蔗糖— — 一旦作物被收割和土地被清理，又可以种植和收割新的作物，通常少于一年。因此，碳氢化合物可称为可再生资源。据估计，植物原料（干重）的总的年产量为1*1011 吨。

化石燃料－天然气、原油和煤，主要用作为能源，而不是作为有机化合物的资源。例如，各种石油分馏物的气体，用于家用烹调和取暖、用作为汽车用的汽油、加热建筑物重燃油，或用于在工业处理以产生的蒸汽。通常，一桶原油的8%用于化学品的生产。下列数据可以说明，为什么化学工业在原油的使用方面与燃料或能源消耗的工业展开着竞争。

显然，若我们愿意使用可代替化石燃料的其他能源，那么这些可替代能源可以利用的，同时，我们自信地预料到在不久的将来，可以用上其他的可替代能源。因此，有必要要去保存宝贵的石油供应以用于化学品的生产。“处理石油的最后一件事情是将之燃烧”该说法是有根据的。注意到这件事很有趣且有益的：早在1894 年门捷列夫（发现元素周期表之俄国科学家）就向当局报道，“石油是太宝贵的资源而不能将之

燃烧掉，应该将之以化学品资源加以保存。

来自于碳水化合物（植物茎杆）的有机化学物质，职务的主要成分是碳水化合物，碳水化合物组成职务的结构。它们为多糖（如纤维素和淀粉），大量的淀粉存在于食物（如谷类、大米和马铃薯）之中，纤维素是组成细胞壁的主要物质，因而广泛存在，可以从木材、棉花等中得到。因此，来自于碳水化合物的化学品的潜力是相当大的，而且该原料可再生。

从碳水化合物得到化学物质的主要途径是通过发酵过程。然而发酵过程不能利用多糖（如维素和淀粉），因此，淀粉必须先收到酸性或酶水解反应生成更简单的糖类（单糖或二糖（如蔗糖），这些较为简单的糖是发酵过程中的）合适的起始原料。

发酵过程是利用单细胞的微生物（一般有酵母菌、真菌、细菌或霉菌）生产特殊化学品。有些发酵农家已用了上千年。最著名的例子为，谷物发酵生产含酒精的饮料。直到1950 年，该方法才成为生产脂肪族有机化学品的最普遍的途径。因为生产的乙醇脱水生成乙烯，而乙烯是合成大量脂肪族化合物的关键中间体。尽管用此方法生产的化学品有所减少，但是用这种方法生产汽车燃料方面存在大量的兴趣。

反映在发酵过程的缺点可分为两方面（1）原料（2）发酵过程。因为植物茎杆是一种农业原料，其生产和收割均为劳动力密集型的过程，所以相比之，它的原料费用高于原油的费用。同时，物料的运输更困难，费用更高。与石化处理过程相比，发酵过程的主要缺点是：其一，时间通常要好几天，相比有些催化石油反应只要几秒；其二，所得的产物通常是以稀的水溶液（浓度<10%）存在，因此，分离和纯化费用较高。因为微生物是活的体系，过程的条件几乎不容许改变。为了增加反应速度，即使相对于小的温升，独有可能会导致微生物的死亡和发酵过程终止。

另一方面，发酵方法的独特优点是，其选择性高，一些结构复杂而很难以合成或者需要多步合成的化合物，通过发酵很容易制得。著名的实例有多种多样的抗生素的生产。如青霉素，头孢菌素和链霉素。

如果也基因工程中快速发展的过程中大量的实际问题得到解决，那么发酵方面的兴趣存在很大的兴趣。在基因工程中。微生物（如细菌）能定制地生产成所需的化学品。然而，因为发酵反应速度慢和产物分离费用高，在不久的将来要实现用发酵方法生产大众化学品（即需求量极大的化学品如依稀，笨。）看来是不可能。

来自于动植物油和脂肪的有机化学品，动植物油脂（常指类肪）是由甘油脂组成，甘油酯为三羟基醇，甘油（丙烷-1，2，3-三醇，丙三醇）。有多种不同的种植物油资源，较为普通的有，大豆，谷物，棕树核，油菜籽，橄榄油，动物脂肪和巨鲸。这些油类可通过溶剂萃取分离得到。有相当大的部分，烹调油脂的形式用食品工业中，用于生产黄油，人选黄油和其他食品（如冰激凌）。这些食品的烷基对人的健康的影响，尤其对血液中的胆固醇的影响，存在着争议。血液中的高胆固醇的含量会引起高血压和心脏病。目前的观点似乎赞成高含量不饱和的基因在降低胆固醇的水平和降低心脏病（发病率）危险是有利的。这引起如下

化学工艺英语篇二：《化学工程与工艺专业英语》全本

Unit 1Chemical Industry

化学工业

Although the use of chemicals dates back to the ancient civilizations, the evolution of what we know as the modern chemical industry started much more recently. It may be considered to have begun during the Industrial Revolution, about 1800, and developed to provide chemicals roe use by other industries. Examples are alkali for soapmaking, bleaching powder for cotton, and silica and sodium carbonate for glassmaking. It will be noted that these are all inorganic chemicals. The organic chemicals industry started in the 1860s with the exploitation of William Hey Perkin‘s discovery if the first synthetic dyestuff—mauve. At the start of the twentieth century the emphasis on research on the applied aspects of chemistry in Germany had paid off handsomely, and by 1914 had resulted in the German chemical industry having 75% of the world market in chemicals. This was based on the discovery of new dyestuffs plus the development of both the contact process for sulphuric acid and the Haber process for ammonia. The later required a major technological breakthrough that of being able to carry out chemical reactions under conditions of very high pressure for the first time. The experience gained with this was to stand Germany in good stead, particularly with the rapidly increased demand for nitrogen-based compounds (ammonium salts for fertilizers and nitric acid for explosives manufacture) with the outbreak of world warⅠin 1914. This initiated profound changes which continued during the inter-war years (1918-1939).

1．化学工业的起源

date bake to/from: 回溯到

dated: 过时的，陈旧的

stand sb. in good stead: 对。。。很有帮助

Since 1940 the chemical industry has grown at a remarkable rate, although this has slowed significantly in recent years. The lion‘s share of this growth has been in the organic chemicals sector due to the development and growth of the petrochemicals area since 1950s. The explosives growth in petrochemicals in the 1960s and 1970s was largely due to the enormous increase in demand for synthetic polymers such as polyethylene, polypropylene, nylon, polyesters and epoxy resins.

The chemical industry today is a very diverse sector of manufacturing industry, within which it plays a central role. It makes thousands of different chemicals which the general public only usually encounter as end or consumer products. These products are purchased because they have the required properties which make them suitable for some particular application, e.g. a non-stick coating for pans or a weedkiller. Thus chemicals are ultimately sold for the effects that they produce.

今天的化学工业已经是制造业中有着许多分支的部门，并且在制造业中起着核心的作用。它生产了数千种不同的化学产

品，而人们通常只接触到终端产品或消费品。这些产品被购买是因为他们具有某些性质适合（人们）的一些特别的用途，例如，用于盆的不粘涂层或一种杀虫剂。这些化学产品归根到底是由于它们能产生的作用而被购买的。

2. Definition of the Chemical Industry

At the turn of the century there would have been little difficulty in defining what constituted the chemical industry since only a very limited range of products was manufactured and these were clearly chemicals, e.g., alkali, sulphuric acid. At present, however, many intermediates to products produced, from raw materials like crude oil through (in some cases) many intermediates to products which may be used directly as consumer goods, or readily converted into them. The difficulty cones in deciding at which point in this sequence the particular operation ceases to be part of the chemical industry‘s sphere of activities. To consider a specific example to illustrate this dilemma, emulsion paints may contain poly (vinyl chloride) / poly (vinyl acetate). Clearly, synthesis of vinyl chloride (or acetate) and its polymerization are chemical activities. However, if formulation and mixing of the paint, including the polymer, is carried out by a branch of the multinational chemical company which manufactured the ingredients, is this still part of the chemical industry of does it mow belong in the decorating industry?

2．化学工业的定义

It is therefore apparent that, because of its diversity of operations and close links in many areas with other industries, there is no simple definition of the chemical industry. Instead each official body which collects and publishes statistics on manufacturing industry will have its definition as to which operations are classified as the chemical industry. It is important to bear this in mind when comparing statistical information which is derived from several sources.

3. The Need for Chemical Industry

The chemical industry is concerned with converting raw materials, such as crude oil, firstly into chemical intermediates and then into a tremendous variety of other chemicals. These are then used to produce consumer products, which make our lives more comfortable or, in some cases such as pharmaceutical produces, help to maintain our well-being or even life itself. At each stage of these operations value is added to the produce and provided this added exceeds the raw material plus processing costs then a profit will be made on the operation. It is the aim of chemical industry to achieve this.

3．对化学工业的需要

It may seem strange in textbook this one to pose the question ―do we need a chemical industry?‖ However trying to answer this question will provide(ⅰ) an indication of the range of the chemical industry‘s activities, (ⅱ) its influence on our lives in everyday terms, and (ⅲ) how great is society‘s need for a chemical industry. Our approach in answering the question will be to consider the industry‘s contribution to meeting and satisfying our major needs. What are these? Clearly food (and drink) and health are paramount. Other which we shall consider in their turn are clothing and (briefly) shelter, leisure and transport.

在这样的一本教科书中提出：“我们需要化学工业吗？”这样一个问题是不是有点奇怪呢？然而，先回答下面几个问题将给我们提供一些信息：（1）化学工业的活动范围，（2）化学工业对我们日常生活的影响，（3）社会对化学工业的需求有多大。在回答这些问题的时候我们的思路将要考虑化学工业在满足和改善我们的主要需求方面所做的贡献。是些什么需求呢？很显

然，食物和健康是放在第一位的。其它我们要考虑的按顺序是衣物、住所、休闲和旅行。

(1) Food. The chemical industry makes a major contribution to food production in at least three ways. Firstly, by making available large quantities of artificial fertilizers which are used to replace the elements (mainly nitrogen, phosphorus and potassium) which are removed as nutrients by the growing crops during modern intensive farming. Secondly, by manufacturing crop protection chemicals, i.e., pesticides, which markedly reduce the proportion of the crops consumed by pests. Thirdly, by producing veterinary products which protect livestock from disease or cure their infections.

(2) Health. We are all aware of the major contribution which the pharmaceutical sector of the industry has made to help keep us all healthy, e.g. by curing bacterial infections with antibiotics, and even extending life itself, e.g. ?–blockers to lower blood pressure.

(3) Clothing. The improvement in properties of modern synthetic fibers over the traditional clothing materials (e.g. cotton and wool) has been quite remarkable. Thus shirts, dresses and suits made from polyesters like Terylene and polyamides like Nylon are crease-resistant, machine-washable, and drip-dry or non-iron. They are also cheaper than natural materials.

Parallel developments in the discovery of modern synthetic dyes and the technology to ―bond‖ them to the fiber has resulted in a tremendous increase in the variety of colors available to the fashion designer. Indeed they now span almost every color and hue of the visible spectrum. Indeed if a suitable shade is not available, structural modification of an existing dye to achieve this can readily be carried out, provided there is a satisfactory market for the product.

Other major advances in this sphere have been in color-fastness, i.e., resistance to the dye being washed out when the garment is cleaned.

这一领域中另一些重要进展是不褪色，即在洗涤衣物时染料不会被洗掉。

(4) Shelter, leisure and transport. In terms of shelter the contribution of modern synthetic polymers has been substantial. Plastics are tending to replace traditional building materials like wood because they are lighter, maintenance-free (i.e. they are resistant to weathering and do not need painting). Other polymers, e.g. urea-formaldehyde and polyurethanes, are important insulating materials for reducing heat losses and hence reducing energy usage.

Plastics and polymers have made a considerable impact on leisure activities with applications ranging from all-weather artificial surfaces for athletic tracks, football pitches and tennis courts to nylon strings for racquets and items like golf balls and footballs made entirely from synthetic materials.

Likewise the chemical industry‘s contribution to transport over the years has led to major improvements. Thus development of improved additives like anti-oxidants and viscosity index improves for engine oil has enabled routine servicing intervals to increase from 3000 to 6000 to 12000 miles. Research and development work has also resulted in improved lubricating oils and greases, and better brake fluids. Yet again the contribution of polymers and plastics has been very striking with the proportion of the total automobile derived from these materials—dashboard, steering wheel, seat padding and covering etc.—now exceeding 40%.

So it is quite apparent even from a brief look at the chemical industry‘s contribution to meeting our major needs that life in the world would be very different without the products of the industry. Indeed the level of a country‘s development may be judged by the production level and sophistication of its chemical industry.

4. Research and Development (R&D) in Chemical Industries

One of the main reasons for the rapid growth of the chemical industry in the developed world has been its great commitment to, and investment in research and development (R&D). A typical figure is 5% of sales income, with this figure being almost doubled for the most research intensive sector, pharmaceuticals. It is important to emphasize that we are quoting percentages here not of profits but of sales income, i.e. the total money received, which has to pay for raw materials, overheads, staff salaries, etc. as well. In the past this tremendous investment has paid off well, leading to many useful and valuable products being introduced to the market. Examples include synthetic polymers like nylons and polyesters, and drugs and pesticides. Although the number of new products introduced to the market has declined significantly in recent years, and in times of recession the research department is usually one of the first to suffer cutbacks, the commitment to R&D remains at a very high level.

4．化学工业的研究和开发。

The chemical industry is a very high technology industry which takes full advantage of the latest advances in electronics and engineering. Computers are very widely used for all sorts of applications, from automatic control of chemical plants, to molecular modeling of structures of new compounds, to the control of analytical instruments in the laboratory.

Individual manufacturing plants have capacities ranging from just a few tones per year in the fine chemicals area to the real giants in the fertilizer and petrochemical sectors which range up to 500,000 tonnes. The latter requires enormous capital investment, since a single plant of this size can now cost $520 million! This, coupled with the widespread use of automatic control equipment, helps to explain why the chemical industry is capital-rather than labor-intensive.

The major chemical companies are truly multinational and operate their sales and marketing activities in most of the countries of

the world, and they also have manufacturing units in a number of countries. This international outlook for operations, or globalization, is a growing trend within the chemical industry, with companies expanding their activities either by erecting manufacturing units in other countries or by taking over companies which are already operating there.

Unit 2 Research and Development

研究和开发

Research and development, or R&D as it is commonly referred to, is an activity which is carried out by all sectors of manufacturing industry but its extent varies considerably, as we will see shortly. Let us first understand, or at least get a feel for, what the terms mean. Although the distinction between research and development is not always clear-cut, and there is often considerable overlap, we will attempt to separate them. In simple terms research can be thought of as the activity which produces new ideas and knowledge whereas development is putting those ideas into practice as new process and products. To illustrate this with an example, predicting the structure of a new molecule which would have a specific biological activity and synthesizing it could be seen as research whereas testing it and developing it to the point where it could be marketed as a new drug could be described as the development part.

研究和开发，或通常所称R&D是制造业各个部门都要进行的一项活动。我们马上可以看到，它的内容变化很大。我们首先了解或先感觉一下这个词的含义。尽管研究和开发的定义总是分得不很清楚，而且有许多重叠的部分，我们还是要试着把它们区分开来。简单说来，研究是产生新思想和新知识的活动，而开发则是把这些思想贯彻到实践中得到新工艺和新产品的行为。可以用一个例子来描述这一点，预测一个有特殊生物活性的分子结构并合成它可以看成是研究而测试它并把它发展到可以作为一种新药推向市场这一阶段则看作开发部分。

1. Fundamental Research and Applied Research

In industry the primary reason for carting out R&D is economic and is to strengthen and improve the company‘s position and profitability. The purpose of R&D is to generate and provide information and knowledge to reduce uncertainty, solve problems and to provide better data on which management can base decisions. Specific projects cover a wide range of activities and time scales, from a few months to 20 years.

1．基础研究和应用研究

在工业上进行研究和开发最主要的原因是经济利益方面，是为了加强公司的地位，提高公司的利润。R&D的目的是做出并提供信息和知识以减低不确定性，解决问题，以及向管理层提供更好的数据以便他们能据此做出决定。特别的项目涵盖很大的活动范围和时间范围，从几个月到20年。

We can pick out a number of areas of R&D activity in the following paragraphs but if we were to start with those which were to

化学工艺英语篇三：化工英语词汇

化工英语词汇

Analysis [?'n?l?s?s] n. (化合物或混合物的)分解，解析，分析

Analyse [??n?laiz] vt. 分析, 分解, 解释

fractionation [,fr?k??n'e??n] n. 分别；分馏法

蒸馏（Distillation）和分馏（Fractionation）是分离、提纯有机化合物最重要最常用的方法之一。 The technologies and processes available to manufacture these products are by fractionation,

hydrogenation and interesterification .

该技术和工艺可以生产这些产品的分馏，加氢和交换。

Fermentation required only a day, and fractionation was not complicated.

发酵只需要一天，分馏并不复杂。

distill [d?s't?l] vt. 提取；蒸馏；使滴下 vi. 蒸馏；滴下；作为精华产生（等于distil）

Distill Recycle 蒸馏回收

Downstream assets include refineries, which distill crude into different chemicals, including gasoline. 下游资产通常包括炼油厂，即从原油中提取出不同的化工产品，比如汽油。

Distillation n. 蒸馏，净化；蒸馏法；精华，蒸馏物英 [,d?st?'le??n] 美 [,d?stl'e??n]

distillation column [化工] 分裂蒸馏塔 ; [化工] 蒸馏塔 ; [化工] 蒸馏柱 ; [化工] 精馏塔

distillation tower 蒸馏塔

He tried to obtain another material by distillation.

他试图通过蒸馏法获得另一种物质。

They may be present in the virgin petroleum and as such, are isolated by physical methods, such as distillation or solvent extraction.

这些原料物质，也许本身就存在于原油当中，因此通过物理方法加以分离，如蒸馏和溶取。

I've always thought distillation, rather than filtering, was the best water purification method and that distilled water is best for drinking.

我一直认为，比起过滤，蒸馏是净化水最好的方式，而蒸馏水是最好的饮用水。

For example, distillation processes that separate out any dissolved minerals by boiling and condensing water require costly amounts of fuel.

例如，蒸馏过程是通过把海水煮沸，使水汽冷凝，将一切溶解矿物质分离出来，这一过程需要大量的燃料。 Thermal distillation involves heat: Boiling water turns it into vapor—leaving the salt behind—that is collected and condensed back into water by cooling it down.

热蒸馏涉及到加热：沸腾的水变成水蒸气 ---盐分留了下来 ---被收集的蒸汽冷却后凝结成水。

All sorts of chemical processes. Distillation, for example, takes advantage of the properties of liquid and gas mixtures.

所有各种化学过程，比如蒸馏，就利用了液相,和气相的混合物。

decoloration [,di:k?l?'rei??n]

n. decolor的变形

decolor [di:'k?l?]

vt. [美国英语] =decolour

The preparation process consists of pretreatment , acid hydrolysis, neutralization , decoloration and concentration.

其制备工艺包括原料的预处理、酸水解、中和、脱色和浓缩。

The yield of monoammonium glycyrrhizinate was 1.30% and content was 95% by the lixiviation, ammoniation, acidation, decoloration and recrystal.

经过浸提、氨化、酸化、脱色、重结晶过程可得到含量为95%的甘草酸铵，甘草酸铵的最终提取率为1.30%。 The decoloration of Reactive Brilliant Red X-3B in Aeration/UV system with Activated Carbon as catalyst was studied, and preliminary analysis about the mechanism of catalysis was done.

本文采用以活性炭作催化剂的曝气/紫外光体系，对染料活性艳红X- 3 B的光氧化脱色进行了试验。

Oxygenate英 ['?ks?d??ne?t; ?k's?d?-] 美 ['ɑks?d??net]

vt. 氧化，充氧；以氧处理；使…与氧化合

The tower-type oxygenate system is a produce based on absorbing and digesting the foreign

technology.

塔式脱氧水制备系统是在国外技术基础上加以吸收消化而开发的一种产品。

This equipment widely used in diversified situations which needs high purity oxygenate water with high precision, good stability and strong reliability.

产品脱氧性能精度高、稳定性好、可靠性强，设备广泛应用于各种需要高纯度脱氧水的应用场合。

Oxidize英 ['?ks?da?z] 美 ['ɑks?'da?z]

vt. 使氧化；使生锈

vi. 氧化

neutralize美 ['n?tr?'la?z] 【化学】中和

solution【化学】溶解；溶解作用溶解状态溶液；溶体

catalyst 英 ['k?t(?)l?st] 美 ['k?t?l?st] n. [物化] 催化剂；刺激因素

The last step is to regenerate the catalyst.

最后一步是将催化剂还原。

active carbon 活性炭

synthesis

英 ['s?nθ?s?s] 美 ['s?nθ?s?s] n. 综合，[化学] 合成；综合体

organic synthesis [化]有机合成

synthesis method 合成法，综合法

chemical synthesis 化学合成

He talked about how to produce medicine by synthesis.

他谈到如何用合成法来制造药品。

Dissolution n. 分解，溶解

Process 过程

PH Scales PH值

Solubility溶解度

Compounds化合物

Analytical chemistry化学分析Qualitative analysis定性分析Quantitative analysis定量分析

Instrumental analysis仪器分析Chromatographic analysis [krom?t?'gr?f?k]色谱分析

Accuracy准确度deviation偏差; 误差; 偏斜

condense 英 [k?n'dens] 美 [k?n'd?ns] vi. 浓缩；凝结vt. 使浓缩；使压缩使压缩，使浓缩；使凝结，使冷凝：

If steam touches cold surfaces, it is condensed into water.

蒸气接触到冷的表面就凝结成水。

Fractional distillation [化工] 分馏

In your fractional distillation condenser.

或在分馏冷凝器。

K. Neon, argon, and krypton are obtained from fractional distillation of liquid air.

氖、氩、氪都能够通过分馏液态空气获得。

(使)凝结

Steam is condensed in the condenser.

蒸汽在冷凝器中凝结。

fractional

[?fr?k??nl]

adj.

微不足道的, 极小的, 极少的

The difference between her wages and yours is only fractional.

她的薪水和你的只差一点点。

分数的; 小数的

Structural formula结构式

Isomer英 ['a?s?m?] 美 ['a?s?m?]

n. [化学] 同分异构物；[核] 同质异能素

Stirring rod搅拌棒

filter滤管

piptette吸液管

Melting pot坩锅

still [化工] distillation still distillation kettle distiller蒸馏釜

Filtration过滤

Catalytic reaction催化反应

catalyst催化剂

Reduction 【化学】还原

ignition【化学】灼烧

filtration n. 过滤；筛选

filtration process 过滤过程

filtration n. filtrate的变形 filtrate ['filtreit] vt., vi. 过滤过滤布

distil [dis'til] vi. 蒸馏；提炼；渗出vt. 蒸馏；提取…的精华；使渗出

[ 过去式 distilled 过去分词 distilled 现在分词 distilling ]

蒸馏(以浓缩或纯化)；用蒸馏法对…进行净化(或纯化、提纯、提取、提炼、浓缩)；用蒸馏法提炼(或提取、生产)；(似)用蒸馏法获得：

We distilled the salt water and made it into drinking water.

我们蒸馏海水使其变成饮用水

用蒸馏法去除(常与off或out连用)：

to distil out impurities

用蒸馏法去除杂质

The physical method include distil-laing, adsorption, etc.

物理方法包括蒸馏法、吸附法等。

Solvent organic solvent [有化] 有机溶剂挥发性溶剂solvent extraction 溶剂萃取；溶剂抽提solvent recovery 溶剂回收

Condenser n. 冷凝器steam condenser 蒸汽冷凝器evaporative condenser 蒸发冷凝器condenser tube 冷凝器管；凝结管

You take that gas phase mixture, and you conden

化学工艺英语

se it in your condenser.

然后用这新得到的气相混合物，在冷凝器中冷凝。

Some new reactors that now use condensers have other design changes that make the condenser more appropriate, he said.

他说，目前使用冷凝器的部分新反应堆也做了其他设计上的变更，使冷凝器更加适用。

Air-conditioning systems—both centralized ones and window units—have three important components: an evaporator, a condenser, and a compressor.

空调系统，包括中央空调和窗口式空调，有三个重要的组成部分：蒸发器，冷凝器，和压缩机。

crystallize 美 ['kr?st?'la?z] vt. 使结晶；明确；使具体化；做成蜜饯vi. 结晶，形成结晶；明确；具体化

He crystallized salt as part of his experiment.

他使盐结晶作为他的实验的一部分。

重结晶 recrystallization ; Recrystallize ; recrystal

crystal

[?krist?l]

水晶

Those fine wine glasses are made of crystal.

那些漂亮的酒杯是用水晶做的

crystalline

[?krist?lain]

adj.

水晶的; 似水晶的; 结晶质的

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