forced ignition

简明释义

强制点火

英英释义

例句

1.In modern gas turbines, forced ignition is critical for achieving optimal performance.

在现代燃气涡轮机中，强制点火对实现最佳性能至关重要。

2.Without forced ignition, the combustion process can become unstable.

没有强制点火，燃烧过程可能变得不稳定。

3.The engineer explained that the system uses forced ignition to ensure the fuel burns efficiently.

工程师解释说，该系统使用强制点火以确保燃料高效燃烧。

4.The safety manual outlines procedures for forced ignition in emergency situations.

安全手册概述了紧急情况下的强制点火程序。

5.The technician adjusted the settings to improve the forced ignition process in the furnace.

技术员调整了设置，以改善炉中的强制点火过程。

作文

In the realm of engineering and physics, the concept of forced ignition plays a crucial role in various applications. Forced ignition refers to the process where a fuel-air mixture is ignited through an external source of energy, rather than relying solely on spontaneous combustion. This method is particularly significant in internal combustion engines, where controlled ignition is essential for efficient operation. The ability to initiate combustion at precise moments can lead to improved performance and reduced emissions, making forced ignition a key factor in modern automotive technology.One of the primary advantages of forced ignition is its reliability. In traditional engines, the timing of ignition can be influenced by several factors, including temperature and pressure. However, with forced ignition, engineers can ensure that the ignition occurs at the optimal moment, regardless of external conditions. This is particularly important in high-performance vehicles, where precision is paramount. By utilizing advanced ignition systems, such as spark plugs or glow plugs, manufacturers can achieve a more consistent and efficient combustion process.Moreover, forced ignition contributes significantly to fuel efficiency. When the ignition timing is optimized, the engine can extract more energy from the fuel consumed. This not only enhances the vehicle's performance but also reduces fuel consumption, which is a critical consideration in today’s environmentally conscious world. As fuel prices continue to rise and concerns about climate change grow, the importance of technologies that promote forced ignition cannot be overstated.In addition to automotive applications, forced ignition is also utilized in various industrial processes. For instance, in power generation, gas turbines often rely on forced ignition to initiate the combustion of natural gas. The ability to control the ignition process allows for more efficient energy production and lower emissions, aligning with global efforts to transition to cleaner energy sources.Furthermore, the use of forced ignition extends to safety applications. In environments where flammable gases may accumulate, controlled ignition systems can prevent dangerous explosions by ensuring that combustion occurs in a safe and regulated manner. This is particularly relevant in industries such as oil and gas, where the risk of uncontrolled ignition can have catastrophic consequences.Looking ahead, the future of forced ignition technology appears promising. With advancements in materials science and electronic control systems, we can expect even more refined methods of ignition that enhance both performance and safety. Research into alternative fuels, such as hydrogen and biofuels, will also necessitate innovations in forced ignition techniques to accommodate different combustion characteristics.In conclusion, forced ignition is a pivotal concept that underpins many modern technologies, particularly in the fields of automotive engineering and industrial processes. Its ability to provide reliable, efficient, and safe ignition solutions makes it indispensable in our quest for improved performance and sustainability. As we continue to innovate and develop new technologies, the principles of forced ignition will undoubtedly remain at the forefront of engineering advancements, shaping the future of energy utilization and combustion systems.

在工程和物理学领域，强制点火的概念在各种应用中起着至关重要的作用。强制点火指的是通过外部能量源点燃燃料-空气混合物的过程，而不是仅仅依赖自发燃烧。这种方法在内燃机中尤为重要，因为控制点火对于高效运行至关重要。能够在精确的时刻启动燃烧可以提高性能并减少排放，使得强制点火成为现代汽车技术中的关键因素。强制点火的主要优势之一是其可靠性。在传统发动机中，点火时机可能会受到温度和压力等多种因素的影响。然而，通过强制点火，工程师可以确保点火在最佳时刻发生，而不受外部条件的影响。这在高性能车辆中尤为重要，因为精度至关重要。通过利用先进的点火系统，如火花塞或预热塞，制造商可以实现更一致和高效的燃烧过程。此外，强制点火对燃油效率的贡献也相当显著。当点火时机得到优化时，发动机可以从消耗的燃料中提取更多的能量。这不仅提高了车辆的性能，还减少了燃料消耗，这在当今环境意识日益增强的世界中是一个关键考虑因素。随着燃料价格的持续上涨和对气候变化的关注，促进强制点火技术的重要性不容小觑。除了汽车应用，强制点火还被广泛用于各种工业过程。例如，在电力生产中，燃气轮机通常依赖于强制点火来启动天然气的燃烧。控制点火过程的能力使得能源生产更加高效，排放更低，与全球向清洁能源转型的努力保持一致。此外，强制点火的使用也扩展到安全应用。在易燃气体可能积聚的环境中，受控点火系统可以通过确保燃烧在安全和受控的方式下发生来防止危险的爆炸。这在石油和天然气等行业中尤其相关，因为失控点火的风险可能造成灾难性的后果。展望未来，强制点火技术的前景看起来很有希望。随着材料科学和电子控制系统的进步，我们可以期待更精细的点火方法，以提高性能和安全性。对氢气和生物燃料等替代燃料的研究也将需要创新的强制点火技术，以适应不同的燃烧特性。总之，强制点火是支撑许多现代技术的关键概念，特别是在汽车工程和工业过程领域。它提供可靠、高效和安全的点火解决方案，使其在我们追求改进性能和可持续性方面不可或缺。随着我们不断创新和开发新技术，强制点火的原则无疑将继续处于工程进步的前沿，塑造能源利用和燃烧系统的未来。