combustion space

简明释义

燃烧室容积

英英释义

例句

1.To improve performance, modifications to the combustion space 燃烧空间 were implemented in the new model.

为了提高性能，新模型对 燃烧空间 燃烧空间 进行了修改。

2.Engineers are studying the combustion space 燃烧空间 to reduce emissions from the vehicle.

工程师们正在研究 燃烧空间 燃烧空间 以减少车辆的排放。

3.The design of the engine must ensure that the combustion space 燃烧空间 is optimized for maximum efficiency.

发动机的设计必须确保 燃烧空间 燃烧空间 优化以达到最大效率。

4.The shape of the combustion space 燃烧空间 can significantly affect the combustion process and efficiency.

燃烧空间 燃烧空间 的形状可以显著影响燃烧过程和效率。

5.In a gas turbine, the combustion space 燃烧空间 plays a crucial role in determining the overall performance.

在燃气涡轮中， 燃烧空间 燃烧空间 在决定整体性能方面起着至关重要的作用。

作文

The concept of combustion space is essential in the study of thermodynamics and combustion engineering. In simple terms, combustion space refers to the volume within a combustion chamber where fuel and oxidizer mix and react to produce heat and energy. Understanding this space is crucial for optimizing the performance of engines, furnaces, and other combustion systems.In many industrial applications, the efficiency of a combustion process can significantly affect overall energy consumption and emissions. The design of the combustion space plays a pivotal role in determining how effectively fuel is burned. For instance, in an internal combustion engine, the shape and size of the combustion space influence the mixing of air and fuel, the speed of combustion, and the amount of energy released.One of the key factors that engineers must consider when designing a combustion space is the turbulence of the flow within that space. Turbulence helps to enhance the mixing of fuel and air, leading to a more complete combustion process. If the combustion space is designed poorly, it can result in incomplete combustion, which not only wastes fuel but also produces harmful emissions such as carbon monoxide and unburned hydrocarbons.Moreover, the temperature within the combustion space is another critical parameter. Higher temperatures generally lead to more efficient combustion, but they can also cause problems such as thermal NOx formation, which contributes to air pollution. Therefore, engineers must find a balance when designing the combustion space to achieve optimal performance without exceeding environmental regulations.In addition to traditional applications, the concept of combustion space is also relevant in emerging technologies such as gas turbines and rocket engines. For example, in rocket propulsion, the combustion space must be carefully designed to withstand extreme pressures and temperatures while ensuring that the propellants combust efficiently to produce thrust.Furthermore, the advent of alternative fuels has added complexity to the design of combustion spaces. Different fuels have varying combustion characteristics, which means that the combustion space must be adaptable to accommodate these differences. This adaptability is vital for the development of cleaner and more sustainable energy solutions.In conclusion, the combustion space is a fundamental element in the field of combustion science. Its design and optimization are crucial for enhancing the efficiency of various combustion systems, reducing emissions, and adapting to new fuel technologies. As we continue to seek more sustainable energy sources, a deeper understanding of the combustion space will be essential for engineers and scientists alike, ensuring that we can harness energy in a way that is both effective and environmentally responsible.

“燃烧空间”这一概念在热力学和燃烧工程的研究中至关重要。简单来说，燃烧空间是指燃烧室内的体积，在此空间内，燃料和氧化剂混合并反应以产生热量和能量。理解这一空间对于优化发动机、炉子和其他燃烧系统的性能至关重要。在许多工业应用中，燃烧过程的效率会显著影响整体能源消耗和排放。燃烧空间的设计在决定燃料燃烧效果方面起着关键作用。例如，在内燃机中，燃烧空间的形状和大小会影响空气和燃料的混合、燃烧速度以及释放的能量量。工程师在设计燃烧空间时必须考虑的一个关键因素是该空间内流动的湍流性。湍流有助于增强燃料和空气的混合，从而导致更完全的燃烧过程。如果燃烧空间设计不当，可能会导致燃烧不完全，这不仅浪费燃料，还会产生有害排放，例如一氧化碳和未燃烧的烃类。此外，燃烧空间内的温度也是一个关键参数。较高的温度通常会导致更高效的燃烧，但也可能导致诸如热NOx形成等问题，这会加剧空气污染。因此，工程师在设计燃烧空间时必须找到一种平衡，以实现最佳性能，同时不超过环境法规。除了传统应用外，燃烧空间的概念在新兴技术中也具有相关性，例如燃气涡轮和火箭发动机。例如，在火箭推进中，燃烧空间必须经过精心设计，以承受极端的压力和温度，同时确保推进剂有效燃烧以产生推力。此外，替代燃料的出现为燃烧空间的设计增加了复杂性。不同的燃料具有不同的燃烧特性，这意味着燃烧空间必须能够适应这些差异。这种适应性对于开发更清洁、更可持续的能源解决方案至关重要。总之，燃烧空间是燃烧科学领域的基本要素。其设计和优化对于提高各种燃烧系统的效率、减少排放以及适应新燃料技术至关重要。随着我们继续寻求更可持续的能源来源，对燃烧空间的深入理解将对工程师和科学家们至关重要，确保我们能够以有效且环保的方式利用能源。