reformate

简明释义

英[rɪˈfɔːˌmeɪt]美[rɪˈfɔːrmeɪt;rɪˈfɔːrmɪt]

n. （碳氢化合物转化的）重整产品；（油气）重整油

英英释义

单词用法

同义词

反义词

例句

1.The highly selective hydrogenation process for the removal of olefins can completely replace the conventional clay treating process for treating the reformate of CCR unit.

采用高选择性加氢脱烯烃技术处理连续重整生成油可取代传统的白土精制工艺。

2.The highly selective hydrogenation process for the removal of olefins can completely replace the conventional clay treating process for treating the reformate of CCR unit.

采用高选择性加氢脱烯烃技术处理连续重整生成油可取代传统的白土精制工艺。

3.Yield of reformate oil, hydrogen and aromatics was increased by 1.3 %, 0.5 % and 2.2%, respectively, when WHSV increased by 20%.

在质量空速提高20%，反应条件基本相同的情况下，重整生成油的收率、纯氢产率和芳烃产率分别可提高1.3%、0.5%和2.2%。

4.A rapid method for determining benzene contents in reformate by Near Infrared Spectroscopy is described in this paper.

介绍了用近红外光谱法对重整生成油的苯含量进行快速测定的方法。

5.The dimethylbenzenes are obtained from catalytic reformate.

二甲苯可从催化重整得到。

6.The oil refinery produced a high-quality reformate that can be used for gasoline blending.

这家炼油厂生产了一种高质量的重整油，可用于汽油混合。

7.After the catalytic process, the reformate had a higher octane rating.

经过催化过程后，重整油的辛烷值更高。

8.The chemical properties of the reformate make it suitable for various industrial applications.

该重整油的化学性质使其适用于多种工业应用。

9.Engineers are analyzing the reformate to improve fuel efficiency.

工程师们正在分析重整油以提高燃油效率。

10.The reformate produced from naphtha is essential for producing high-octane fuels.

从石脑油中产生的重整油对生产高辛烷值燃料至关重要。

作文

In the world of chemistry and engineering, the term reformate refers to a product derived from the reforming process, which is essential in the production of high-octane gasoline. The significance of reformate lies not only in its application but also in its contribution to environmental sustainability. As industries strive to reduce their carbon footprint, understanding the role of reformate becomes increasingly important. This essay will explore the definition, production process, and environmental implications of reformate, highlighting its importance in modern fuel technology. To begin with, reformate is primarily produced through catalytic reforming, a process that converts low-octane naphthas into high-octane fuels. This transformation involves the rearrangement of hydrocarbon molecules, which enhances the octane rating of the fuel. The resulting reformate contains a mixture of aromatic hydrocarbons, such as benzene, toluene, and xylenes, which are crucial for formulating gasoline that meets stringent performance standards. The production of reformate plays a vital role in the refining industry. As global demand for cleaner-burning fuels increases, refineries are investing in advanced technologies to optimize the catalytic reforming process. This optimization not only improves the yield of reformate but also reduces the generation of by-products that could harm the environment. Moreover, the integration of renewable resources into the reforming process is an emerging trend that promises to enhance the sustainability of fuel production. Another important aspect of reformate is its impact on air quality. High-octane fuels derived from reformate combustion produce fewer emissions compared to traditional fuels. This reduction in harmful pollutants is critical in urban areas where air quality is often compromised. By utilizing reformate, we can help mitigate the adverse effects of vehicular emissions, contributing to healthier communities and a cleaner environment. Furthermore, the chemical properties of reformate make it a valuable feedstock for the petrochemical industry. Many of the components found in reformate are used to produce various chemicals and materials, including plastics, synthetic fibers, and solvents. This versatility underscores the economic significance of reformate beyond its role as a fuel component, showcasing its importance in the broader context of industrial applications. However, the production and use of reformate are not without challenges. The refining process can be energy-intensive, leading to concerns about its overall environmental impact. To address these issues, researchers are exploring alternative methods of producing reformate, including the use of biomass and other renewable resources. These innovations have the potential to create a more sustainable pathway for reformate production, aligning with global efforts to transition towards greener energy solutions. In conclusion, reformate is a crucial component in the landscape of modern fuel technology. Its production through catalytic reforming not only enhances fuel quality but also contributes to environmental sustainability. As industries continue to evolve, the importance of reformate will likely grow, driving advancements in both fuel efficiency and emissions reduction. Understanding the multifaceted role of reformate is essential for anyone interested in the future of energy and its impact on our planet.

在化学和工程领域，术语reformate指的是通过重整过程获得的产品，这在高辛烷值汽油的生产中至关重要。reformate的重要性不仅体现在其应用上，还体现在其对环境可持续性的贡献上。随着各行业努力减少碳足迹，理解reformate的作用变得越来越重要。本文将探讨reformate的定义、生产过程及其环境影响，突出其在现代燃料技术中的重要性。 首先，reformate主要通过催化重整生产，该过程将低辛烷值的石脑油转化为高辛烷值的燃料。这一转变涉及碳氢化合物分子的重组，从而提高燃料的辛烷值。最终得到的reformate包含多种芳香烃，如苯、甲苯和二甲苯，这些都是配制符合严格性能标准的汽油所必需的。 reformate的生产在炼油行业中发挥着至关重要的作用。随着全球对清洁燃料的需求不断增加，炼油厂正在投资先进技术以优化催化重整过程。这种优化不仅提高了reformate的产量，还减少了可能对环境造成危害的副产品的产生。此外，将可再生资源融入重整过程是一个新兴趋势，承诺提升燃料生产的可持续性。 reformate的另一个重要方面是其对空气质量的影响。使用由reformate燃烧生成的高辛烷值燃料相比于传统燃料排放更少的污染物。这种有害污染物的减少在城市地区尤为关键，因为这些地区的空气质量往往受到威胁。通过利用reformate，我们可以帮助减轻机动车排放的负面影响，促进更健康的社区和更清洁的环境。 此外，reformate的化学特性使其成为石化工业中一种宝贵的原料。许多在reformate中发现的成分用于生产各种化学品和材料，包括塑料、合成纤维和溶剂。这种多功能性强调了reformate在作为燃料成分之外的经济重要性，展示了其在更广泛的工业应用中的重要性。 然而，reformate的生产和使用并非没有挑战。炼油过程可能是能源密集型的，这引发了关于其整体环境影响的担忧。为了应对这些问题，研究人员正在探索生产reformate的替代方法，包括利用生物质和其他可再生资源。这些创新有潜力为reformate的生产创造更可持续的路径，与全球向更绿色能源解决方案过渡的努力保持一致。 总之，reformate是现代燃料技术领域中的一个关键组成部分。通过催化重整生产的reformate不仅提高了燃料质量，还促进了环境的可持续性。随着各行业的不断发展，reformate的重要性可能会进一步增强，推动燃料效率和减排的进步。理解reformate的多方面角色对于任何对能源未来及其对地球影响感兴趣的人来说都是至关重要的。