turbulent burner

简明释义

湍流式燃烧器

英英释义

例句

1.The engineer explained how the turbulent burner 湍流燃烧器 improves fuel efficiency in industrial applications.

工程师解释了如何使用湍流燃烧器 提高工业应用中的燃料效率。

2.The turbulent burner was designed to handle a wide range of fuel types, making it versatile for different industries.

该湍流燃烧器 被设计为能够处理多种燃料类型，使其在不同工业中具有多功能性。

3.The turbulent burner is essential for achieving high combustion temperatures in gas turbines.

在燃气涡轮中，湍流燃烧器 对于达到高燃烧温度至关重要。

4.During the demonstration, the turbulent burner showed a significant reduction in emissions compared to traditional burners.

在演示过程中，湍流燃烧器 与传统燃烧器相比，显示出显著的排放减少。

5.In the lab, we tested the turbulent burner 以评估其性能 under various conditions.

在实验室中，我们测试了湍流燃烧器 以评估其在不同条件下的性能。

作文

In the realm of combustion technology, the term turbulent burner refers to a specific type of burner that promotes a highly chaotic and mixed flow of fuel and air. This design is crucial for achieving efficient combustion, as it enhances the mixing process between the fuel and oxidizer, leading to more complete combustion and reduced emissions. A turbulent burner operates by creating turbulence in the combustion chamber, which increases the surface area of the fuel particles exposed to oxygen, thereby promoting a faster and more efficient reaction. The significance of turbulent burners can be observed in various applications, ranging from industrial furnaces to power generation systems. In these settings, the efficiency of energy conversion is paramount. Traditional burners often struggle with incomplete combustion, resulting in wasted fuel and increased pollutants. However, by utilizing a turbulent burner, engineers can significantly improve the overall performance of combustion systems. The turbulent flow generated within the burner ensures that the fuel and air are mixed thoroughly, leading to a more uniform temperature distribution and optimal combustion conditions.Moreover, turbulent burners are particularly beneficial in scenarios where rapid changes in load demand occur. For example, in power plants, the ability to quickly adjust to varying energy needs is essential. Turbulent burners can respond to these fluctuations by modifying the combustion process dynamically, thus maintaining efficiency and reducing the likelihood of harmful emissions. This adaptability makes them an attractive choice for modern energy systems focused on sustainability and environmental responsibility.Another notable advantage of turbulent burners is their contribution to the reduction of nitrogen oxides (NOx) emissions. NOx gases are a significant concern in air quality management due to their role in forming smog and acid rain. By ensuring more complete combustion through enhanced mixing, turbulent burners help lower the formation of these harmful byproducts, aligning with global efforts to mitigate climate change and protect public health.Despite their many benefits, the design and operation of turbulent burners require careful consideration. Engineers must account for factors such as fuel type, combustion chamber geometry, and operating conditions to ensure optimal performance. Computational fluid dynamics (CFD) simulations are often employed to analyze the flow characteristics within the burner, allowing for precise adjustments to enhance its efficiency.In conclusion, the concept of a turbulent burner is integral to advancing combustion technology. Its ability to facilitate efficient fuel-air mixing leads to improved energy conversion, reduced emissions, and greater adaptability in response to changing operational demands. As industries continue to prioritize sustainability, the adoption of turbulent burners will likely play a pivotal role in shaping the future of energy production and consumption. Understanding and implementing this technology can lead to significant advancements in both environmental protection and energy efficiency, making it a crucial topic for engineers and researchers alike.

在燃烧技术领域，术语turbulent burner指的是一种促进燃料和空气高度混合流动的特定类型的燃烧器。这种设计对于实现高效燃烧至关重要，因为它增强了燃料与氧化剂之间的混合过程，从而导致更完全的燃烧和减少排放。turbulent burner通过在燃烧室内产生湍流来工作，这增加了燃料颗粒暴露于氧气的表面积，从而促进更快、更高效的反应。turbulent burners的重要性可以在各种应用中观察到，从工业炉到发电系统。在这些环境中，能源转换的效率至关重要。传统燃烧器常常面临不完全燃烧的问题，导致燃料浪费和污染物增加。然而，通过利用turbulent burner，工程师可以显著提高燃烧系统的整体性能。燃烧器内产生的湍流确保燃料和空气充分混合，从而实现更均匀的温度分布和最佳的燃烧条件。此外，turbulent burners在负载需求快速变化的情况下尤其有利。例如，在发电厂中，快速适应不同能源需求的能力至关重要。湍流燃烧器可以通过动态调整燃烧过程来响应这些波动，从而保持效率并减少有害排放的可能性。这种适应性使它们成为现代以可持续性为重点的能源系统的理想选择。另一个显著的优点是turbulent burners有助于减少氮氧化物（NOx）排放。NOx气体是空气质量管理中的一个重大问题，因为它们在形成烟雾和酸雨中起着重要作用。通过确保更完全的燃烧，增强混合，turbulent burners帮助降低这些有害副产品的形成，符合全球减缓气候变化和保护公共健康的努力。尽管有许多好处，但turbulent burners的设计和操作需要仔细考虑。工程师必须考虑燃料类型、燃烧室几何形状和操作条件等因素，以确保最佳性能。计算流体动力学（CFD）模拟通常用于分析燃烧器内的流动特性，从而允许对其效率进行精确调整。总之，turbulent burner的概念对于推进燃烧技术至关重要。它促进高效的燃料-空气混合，导致能量转换的改善、排放的减少以及对变化的操作需求的更大适应性。随着各行业继续优先考虑可持续性，采用turbulent burners将可能在塑造未来能源生产和消费方面发挥关键作用。理解和实施这一技术可以在环境保护和能源效率方面带来显著进展，使其成为工程师和研究人员共同关注的重要主题。