combustion zone

简明释义

燃烧区

英英释义

例句

1.In gas turbines, the combustion zone (燃烧区) is critical for achieving high performance.

在燃气涡轮中，燃烧区对实现高性能至关重要。

2.The engineer analyzed the temperature distribution in the combustion zone (燃烧区) to optimize fuel efficiency.

工程师分析了燃烧区的温度分布，以优化燃料效率。

3.The design of the combustion zone (燃烧区) affects emissions and overall engine efficiency.

燃烧区的设计影响排放和整体发动机效率。

4.The combustion zone (燃烧区) temperature must be controlled to prevent damage to the engine.

燃烧区的温度必须控制，以防止对发动机的损坏。

5.Monitoring the combustion zone (燃烧区) helps in diagnosing engine performance issues.

监测燃烧区有助于诊断发动机性能问题。

作文

The term combustion zone refers to a specific area within a combustion system where the fuel and oxidizer react to produce heat and light. This concept is fundamental in various fields, including engineering, environmental science, and energy production. Understanding the dynamics of the combustion zone is crucial for optimizing performance and reducing emissions in engines, furnaces, and other combustion devices.In a typical combustion process, the combustion zone is where the temperature reaches its peak, allowing the chemical reactions to occur efficiently. For instance, in an internal combustion engine, the combustion zone is located within the cylinder, where the fuel-air mixture ignites. The design of this zone significantly affects the efficiency of the engine and the amount of pollutants it emits. Engineers often focus on enhancing the conditions within the combustion zone to achieve complete combustion, which minimizes unburned hydrocarbons and carbon monoxide.Moreover, the combustion zone is not only limited to engines but also plays a vital role in power plants. In coal-fired power plants, the combustion zone is found in the boiler, where coal is burned to generate steam that drives turbines. The efficiency of this process is heavily influenced by the design of the combustion zone, as it determines how effectively the coal burns and how much energy is produced. Innovations in combustion technology aim to create more controlled combustion zones that can operate at higher efficiencies while producing fewer emissions.In addition to engineering applications, understanding the combustion zone has significant implications for environmental science. The emissions from combustion processes contribute to air pollution and climate change. By studying the combustion zone, scientists can develop strategies to reduce harmful emissions and improve air quality. For example, advancements in catalytic converters and exhaust gas recirculation systems are designed to optimize the combustion zone to ensure that more fuel is burned completely, thereby reducing the release of nitrogen oxides and particulate matter into the atmosphere.Furthermore, the combustion zone can vary based on the type of fuel being used. Different fuels have distinct combustion characteristics, which influence the temperature and pressure within the combustion zone. For instance, natural gas burns cleaner than coal, resulting in a different combustion zone profile. This variability necessitates tailored approaches when designing combustion systems for different fuels to maximize efficiency and minimize environmental impact.In conclusion, the combustion zone is a critical component of combustion processes across various applications. Its understanding is essential for engineers looking to enhance performance and reduce emissions in engines and power plants. Moreover, it plays a significant role in environmental science, helping to address challenges related to air quality and climate change. As technology progresses, continued research into optimizing the combustion zone will be vital for creating sustainable energy solutions that meet the needs of our growing population while protecting the environment.

术语combustion zone指的是燃烧系统内的特定区域，在该区域中，燃料和氧化剂反应以产生热量和光。这个概念在工程、环境科学和能源生产等多个领域中都是基础。理解combustion zone的动态对于优化性能和减少发动机、炉子以及其他燃烧设备中的排放至关重要。在典型的燃烧过程中，combustion zone是温度达到峰值的地方，使得化学反应能够高效进行。例如，在内燃机中，combustion zone位于气缸内，燃料和空气混合物在这里点燃。这个区域的设计显著影响着发动机的效率以及它排放的污染物。工程师通常专注于改善combustion zone内的条件，以实现完全燃烧，从而最小化未燃烧的碳氢化合物和一氧化碳。此外，combustion zone不仅限于发动机，它在发电厂中也发挥着重要作用。在燃煤发电厂中，combustion zone位于锅炉内，煤在这里燃烧以产生驱动涡轮的蒸汽。这个过程的效率受到combustion zone设计的重大影响，因为它决定了煤燃烧的有效性和产生的能量。燃烧技术的创新旨在创建更受控的combustion zone，使其能够在更高的效率下运作，同时产生更少的排放。除了工程应用外，理解combustion zone对环境科学有重要影响。燃烧过程中的排放物会导致空气污染和气候变化。通过研究combustion zone，科学家可以制定减少有害排放和改善空气质量的策略。例如，催化转化器和废气再循环系统的进步旨在优化combustion zone，以确保更多的燃料被完全燃烧，从而减少氮氧化物和颗粒物释放到大气中的数量。此外，combustion zone可能根据所使用的燃料类型而有所不同。不同的燃料具有不同的燃烧特性，这影响着combustion zone内的温度和压力。例如，天然气比煤更清洁，导致不同的combustion zone特征。这种变异性要求在为不同燃料设计燃烧系统时采取量身定制的方法，以最大化效率并最小化环境影响。总之，combustion zone是各种应用中燃烧过程的关键组成部分。理解这一点对于希望提高发动机和发电厂性能及减少排放的工程师至关重要。此外，它在环境科学中也扮演着重要角色，有助于应对与空气质量和气候变化相关的挑战。随着技术的进步，继续研究优化combustion zone将对创造可持续的能源解决方案至关重要，以满足我们不断增长的人口需求，同时保护环境。