distillatory

简明释义

英[dɪsˈtɪlətəri]美[dɪsˈtɪləˌtɑːri]

adj. 蒸馏用的

n. 蒸馏器

英英释义

单词用法

同义词

反义词

例句

1.Therefore, combined with mass and heat transfer in liquid film, it is important for optimizing operation condition and enlarging equipment to study rarefied gas flowing in distillatory.

因此，结合分子蒸馏液膜传质和传热过程，研究蒸发区间稀薄气体的运动规律对工艺优化和分子蒸馏器放大生产具有十分重要的意义。

2.Therefore, combined with mass and heat transfer in liquid film, it is important for optimizing operation condition and enlarging equipment to study rarefied gas flowing in distillatory.

因此，结合分子蒸馏液膜传质和传热过程，研究蒸发区间稀薄气体的运动规律对工艺优化和分子蒸馏器放大生产具有十分重要的意义。

3.The distillatory process is essential in producing high-purity chemicals.

这个蒸馏的过程在生产高纯度化学品中至关重要。

4.In the lab, we set up a distillatory apparatus to separate the components of the mixture.

在实验室，我们设置了一个蒸馏的设备来分离混合物的成分。

5.The distillatory method used here is based on differences in boiling points.

这里使用的蒸馏的方法是基于沸点的差异。

6.A well-designed distillatory system can significantly improve yield.

一个设计良好的蒸馏的系统可以显著提高产量。

7.The distillatory column was filled with packing material to enhance separation efficiency.

这个蒸馏的塔填充了填料材料以提高分离效率。

作文

In the world of chemistry and manufacturing, the term distillatory refers to a process or apparatus used for distillation. Distillation is a fundamental technique that separates components of a mixture based on differences in their boiling points. This method is widely employed in various industries, including the production of alcoholic beverages, petrochemicals, and essential oils. Understanding the distillatory process is crucial for anyone pursuing a career in chemistry or related fields. At its core, the distillatory process involves heating a liquid mixture to create vapor and then cooling that vapor to produce a liquid. This cycle allows for the separation of substances, as different compounds will evaporate at different temperatures. For instance, in the production of whiskey, the fermented mash is heated in a still, where alcohol vapors rise and are collected, while heavier components remain in the still. This selective separation is what makes the distillatory method so valuable. The design of distillatory equipment can vary significantly depending on the desired outcome. Simple distillation setups might consist of a heat source, a boiling flask, and a condenser, while more complex systems may include multiple columns and stages for fractional distillation. Fractional distillation, a more advanced form of distillatory, allows for the separation of mixtures with closer boiling points by using a fractionating column. This is particularly useful in the petrochemical industry, where crude oil is refined into gasoline, diesel, and other products. Moreover, the efficiency of a distillatory process can be influenced by several factors, including temperature, pressure, and the presence of impurities. For example, operating under reduced pressure can lower boiling points, making the distillation process more energy-efficient. Additionally, understanding the physical and chemical properties of the substances involved can lead to better optimization of the distillatory process, resulting in higher yields and purer products. In the realm of essential oils, distillatory methods such as steam distillation are commonly used to extract volatile compounds from plant materials. This technique not only preserves the delicate aromas but also ensures that the therapeutic properties of the oils are retained. The careful application of distillatory processes in this context highlights the importance of precision and control in chemical engineering. In conclusion, the concept of distillatory is integral to many scientific and industrial applications. Its ability to separate and purify substances makes it an invaluable tool in chemistry. Whether it's in the creation of fine spirits, the refinement of fuels, or the extraction of natural compounds, the distillatory process demonstrates the intersection of science and art. As technology advances, the methods and efficiency of distillatory processes will continue to evolve, opening new avenues for innovation and discovery in various fields.

在化学和制造的世界中，术语distillatory指的是用于蒸馏的过程或设备。蒸馏是一种基本技术，根据混合物中组分的沸点差异进行分离。这种方法广泛应用于各个行业，包括酒精饮料、石油化工和精油的生产。理解distillatory过程对于任何追求化学或相关领域职业的人来说都是至关重要的。 从根本上说，distillatory过程涉及加热液体混合物以产生蒸汽，然后冷却该蒸汽以产生液体。这个循环允许物质的分离，因为不同的化合物会在不同的温度下蒸发。例如，在威士忌的生产中，发酵的麦芽在蒸馏器中加热，酒精蒸汽上升并被收集，而较重的成分则留在蒸馏器中。这种选择性分离使得distillatory方法如此有价值。 distillatory设备的设计可能因所需结果而有显著不同。简单的蒸馏装置可能由热源、沸腾烧瓶和冷凝器组成，而更复杂的系统可能包括多个柱和分馏蒸馏的阶段。分馏蒸馏是distillatory的更高级形式，通过使用分馏柱允许分离沸点更接近的混合物。这在石油化工行业尤为有用，因为原油被精炼成汽油、柴油和其他产品。 此外，distillatory过程的效率可能受到多个因素的影响，包括温度、压力和杂质的存在。例如，在减压下操作可以降低沸点，使蒸馏过程更加节能。此外，了解所涉及物质的物理和化学性质可以更好地优化distillatory过程，从而获得更高的产量和更纯的产品。 在精油领域，像蒸汽蒸馏这样的distillatory方法通常用于从植物材料中提取挥发性化合物。这种技术不仅保留了细腻的香气，还确保了油的治疗特性得以保留。在这种背景下，distillatory过程的谨慎应用突显了化学工程中精确和控制的重要性。 总之，distillatory的概念对于许多科学和工业应用至关重要。它分离和净化物质的能力使其成为化学中不可或缺的工具。无论是在创造精美的烈酒、精炼燃料还是提取天然化合物方面，distillatory过程展示了科学与艺术的交汇。随着技术的进步，distillatory过程的方法和效率将继续演变，为各种领域的创新和发现开辟新的途径。