发布时间 : 星期二 文章《化学工程与工艺专业英语》最全翻译最新整理 - 图文更新完毕开始阅读
100 liters capacity) which will be invaluable in the design of the actual manufacturing plant. If the plant is to be a very large capacity, continuously operating one, e.g. petrochemical or ammonia, then a pilot plant will first be built and operated to test out the process and acquire more data, these semi-technical or pilot plants will be required for testing, e.g., a pesticide, or customer evaluation, e.g., a new polymer.
对一个新产品进行开发要考虑产品生产的规模、产生的副产品以及分离/回收,产品所要求的纯度。在开发阶段利用中试车间(最大容量可达100升)获得的数据设计实际的制造厂是非常宝贵的,例如石油化工或氨的生产。要先建立一个中试车间,运转并测试流程以获得更多的数据。他们需要测试产品的性质,如杀虫剂,或进行消费评估,如一种新的聚合物。
Note that by-products can has a major influence on the economics of a chemical process. Phenol manufacture provides a striking example of this. The original route, the benzenesulphonic acid route, has become obsolete because demand for its by-produce sodium sulfite (2.2 tons/l ton phenol) has dried up. Its recovery and disposal will therefore be an additional charge on the process, thus increasing the cost of the phenol. In contrast the cumene route owes its economic advantage over all the other routes to the strong demand for the by-product acetone (0.6 tons/l ton phenol).The sale of this therefore reduces the net cost of the phenol.
注意,副产品对于化学过程的经济效益也有很大的影响。酚的生产就是一个有代表性的例子。早期的方法,苯磺酸方法,由于它的副产品亚硫酸钠需求枯竭而变的过时。亚硫酸钠需回收和废置成为生产过程附加的费用,增加了生产酚的成本。相反,异丙基苯方法,在经济效益方面优于所有其他方法就在于市场对于它的副产品丙酮的迫切需求。丙酮的销售所得降低了酚的生产成本。
A major part of the process development activity for a mew plant is to minimize, or ideally prevent by designing out, waste production and hence possible pollution. The economic and environmental advantages of this are obvious.
对一个新产品进行工艺开发的一个重要部分是通过设计把废品减到最低,或尽可能地防止可能的污染,这样做带来的经济利益和对环境的益处是显而易见的。
Finally it should be noted that process development requires a big team effort between chemists, chemical engineers, and electrical and mechanical engineers to be successful.
最后要注意,工业开发需要包括化学家、化学工程师、电子和机械工程师这样一支庞大队伍的协同合作才能取得成功。
(3) Process improvement. Process improvement relates to processes which are already operating. It may be a problem that has arisen and stopped production. In this situation there is a lot of pressure to find a solution as soon as possible so that production can restart, since ?down time‘ costs money.
(3)工艺改进。工艺改进与正在进行的工艺有关。它可能出现了某个问题使生产停止。在这种情形下,就面临着很大的压力要尽快地解决问题以便生产重新开始,因为故障期耗费资财。
down time: 故障期
More commonly, however, process improvement will be directed at improving the profitability of the process. This might be achieved in a number of ways. For example, improving the yield by optimizing the process, increasing the capacity by introducing a new catalyst, or lowering the energy requirements of the process. An example of the latter was the introduction of turbo compressors in the production of ammonia by the Haber process. This reduced utility costs (mainly electricity) from $6.66 to %0.56 per ton of ammonia produced. Improving the quality of the product, by process modification, may lead to new markets for
the product.
然而,更为常见的,工艺改进是为了提高生产过程的利润。这可以通过很多途径实现。例如通过优化流程提高产量,引进新的催化剂提高效能,或降低生产过程所需要的能量。可说明后者的一个例子是在生产氨的过程中涡轮压缩机的引进。这使生产氨的成本(主要是电)从每吨6.66美元下降到0.56美元。通过工艺的改善提高产品质量也会为产品打开新的市场。
In recent years, however, the most important process improvement activity has been to reduce the environmental impact of the process, i.e., to prevent the process causing any pollution. Clearly there have been two interlinked driving forces for this. Firstly, the public‘s concern about the safety of chemicals and their effect on the environment, and the legislation which has followed as a result of this. Secondly the cost to the manufacturer of having to treat waste (i.e., material which cannot be recovered and used r sold) so that it can be safely disposed of, say by pumping into a river. This obviously represents a charge on the process which will increase the cost of the chemical being made. The potential for improvement by reducing the amount of waste is self-evident.
然而,近年来,最重要的工艺改进行为主要是减少生产过程对环境的影响,亦即防止生产过程所引起的污染。很明显,有两个相关连的因素推动这样做。第一,公众对化学产品的安全性及其对环境所产生影响的关注以及由此而制订出来的法律;第二,生产者必须花钱对废物进行处理以便它能安全地清除,比如说,排放到河水中。显然这是生产过程的又一笔费用,它将增加所生产化学产品的成本。通过减少废物数量提高效益其潜能是不言而喻的。
Note, however, with a plant which has already been built and is operating there are usually only very limited physical changes which can be made to the plant to achieve the above aims. Hence the importance, already mentioned, of eliminating waste production at the design stage of a new plant. Conserving energy and thus reducing energy cost has been another major preoccupation in recent years.
然而,请注意,对于一个已经建好并正在运行的工厂来说,只能做一些有限的改变来达到上述目的。因此,上面所提到的减少废品的重要性应在新公厂的设计阶段加以考虑。近年来另一个当务之急是保护能源及降低能源消耗。
(4) Applications development. Clearly the discovery of new applications or uses for a product can increase or prolong its profitability. Not only does this generate more income but the resulting increased scale of production can lead to lower unit costs and increased profit. An example is PVC whose early uses included records and plastic raincoats. Applications which came later included plastic bags and particularly engineering uses in pipes and guttering.
(4)应用开发。显然发掘一个产品新的用处或新的用途能拓宽它的获利渠道。这不仅能创造更多的收入,而且由于产量的增加使单元生产成本降低,从而使利润提高。举例来说,PVC早期是用来制造唱片和塑料雨衣的,后来的用途扩展到塑料薄膜,特别是工程上所使用的管子和排水槽。
Emphasis has already been placed on the fact that chemicals are usually purchased for the effect, or particular use, or application which they have. This often means that there will be close liaison between the chemical companies‘ technical sales representatives and the customer, and the level of technical support for the customer can be a major factor in winning sales. Research and development chemists provide the support for these applications developments. An example is CF3CH3F. This is the first of the CFC replacements and has been developed as a extracting natural products from plant materials. In no way was this envisaged when the compound was first being made for use as a refrigerant gas, but it clearly is an example of applications development.
我们已经强调了化学产品是由于它们的效果,或特殊的用途、用处而得以售出这个事实。这就意味着化工产品公司的技术销售代表与顾客之间应有密切的联系。对顾客的技术支持水平往往是赢得销售的一个重要的因素。进行研究和开发的化学家们为这些应用开发提供了帮助。CH3CH3F的制造就是一个例子。它最开始是用来做含氟氯烃的替代物作冷冻剂的。然而近来发现它还可以用作从植物中萃取出来的天然物质的溶解剂。当它作为制冷剂被制造时,固然没有预计到这一点,但它显然也是应用开发的一个例子。
3.Variations in R&D Activities across the Chemical Industry
Both the nature and amount of R&D carried out varies significantly across the various sectors of the chemical industry. In sectors which involve largescale production of basic chemicals and where the chemistry, products and technology change only slowly because the process are mature, R&D expenditure is at the lower end of the range for the chemical industry. Most of this will be devoted to process improvement and effluent treatment. Examples include ammonia, fertilizers and chloralkali production from the inorganic side, and basic petrochemical intermediates such a ethylene from the organic side.
3.化工行业中研究与开发活动的变化
化学工业的不同部门所进行的R&D的性质与数量都有很大的变化。与大规模生产的基础化工产品有关的部门中,化学产品和技术变化都很慢,因为流程已很成熟。R&D经费支出属于化工行业中低的一端,而且大部分的费用是用于过程改进和废水处理。无机方面的例子有氨、肥料和氯碱的生产,有机方面的如乙烯等一些基础石油化学的中间产物。
At the other end of the scale lie pharmaceuticals and pesticides (or plant protection products). Here there are immense and continuous efforts to synthesize new molecules which exert the desired, specific biological effect. A single company may generate 10,000 new compounds for screening each year. Little wonder that some individual pharmaceutical company‘s annual R&D expenditure is now approaching $1000 million! Expressing this in a different way they spend in excess of 14% of sales income (note not profits) on R&D.
不一样规模生产的是药品和除草剂。人们付出了巨大而持续的努力以合成能产生所希望的、特殊的生物作用的新分子。一家公司每年可能要合成10,000新化合物以供筛选。可以想象一些医药公司其每年的R&D经费支出高达100亿美元。换句话说,他们把超过14%的销售收入投入在R&D上。
Unit 3 Typical Activities of Chemical Engineers
化学工程师的例行工作
The classical role of the chemical engineer is to take the discoveries made by the chemist in the laboratory and develop them into money--making, commercial-scale chemical processes. The chemist works in test tubes and Parr bombs with very small quantities of reactants and products (e.g., 100 ml), usually running ―batch‖, constant-temperature experiments. Reactants are placed in a small container in a constant temperature bath. A catalyst is added and the reactions proceed with time. Samples are taken at appropriate intervals to follow the consumption of the reactants and the production of products as time progresses.
化学工程师经典的角色是把化学家在实验室里的发现拿来并发展成为能赚钱的、商业规模的化学过程。化学家用少量的反应物在试管和派式氧弹中反应相应得到少量的生成物,所进行的通常是间歇性的恒温下的实验,反应物放在很小的置于恒温水槽的容器中,加点催化剂,反应继续进行,随时间推移,反应物被消耗,并有生成物产生,产物在合适的间歇时间获得。
By contrast, the chemical engineer typically works with much larger quantities of material and with very large (and expensive) equipment. Reactors can hold 1,000 gallons to 10,000 gallons or more. Distillation columns can be over 100 feet high and 10 to 30 feet in diameter. The capital investment for one process unit in a chemical plant may exceed $100 million!
与之相比,化学工程师通常面对的是数量多得多的物质和庞大的(昂贵的)设备。反应器可以容纳1000 到10,000加仑甚至更多。蒸馏塔有100英尺多高,直径10到30英尺。化工厂一个单元流程的投资可能超过1亿美元。
The chemical engineer is often involved in ―scaling up‖ a chemist-developed small-scale reactor and separation system to a very large commercial plant. The chemical engineer must work closely with the chemist in order to understand thoroughly the chemistry involved in the process and to make sure that the chemist gets the reaction kinetic data and the physical property data needed to design, operate, and optimize the process. This is why the chemical engineering curriculum contains so many chemistry courses.
在把化学家研制的小型反应器及分离系统―放大‖到很大的商业化车间时,通常需要化学工程师的参与。为了彻底了解过程中的化学反应,化学工程师必须与化学家密切合作以确保能得到所需要的反应的动力学性质和物理性质参数以进行设计、运转和优选流程。这就是为什么化工课程要包括那么多的化学类课程的原因。
The chemical engineer must also work closely with mechanical, electrical, civil, and metallurgical engineers in order to design and operate the physical equipment in a plant--the reactors, tanks, distillation columns, heat exchangers, pumps, compressors, Control and instrumentation devices, and so on. One big item that is always on such an equipment list is piping. One of the most impressive features f a typical chemical plant is the tremendous number of pipes running all over the site, literally hundreds of miles in many plants. These pipes transfer process materials (gases and liquids) into and out of the plant. They also carry utilities (steam, cooling water, air, nitrogen, and refrigerant) to the process units.
化学工程师还必须与机械、电子、土木建筑和冶金工程师密切协作以设计和操作工厂的