detonating temperature
简明释义
爆发温度
英英释义
The minimum temperature at which a substance, typically an explosive, will detonate or undergo a rapid chemical reaction, resulting in an explosion. | 使物质(通常是爆炸物)发生爆炸或快速化学反应的最低温度,从而导致爆炸。 |
例句
1.Engineers need to consider the detonating temperature when designing safety protocols for handling explosives.
工程师在设计处理爆炸物的安全协议时,需要考虑爆炸温度。
2.During the experiment, we observed that the detonating temperature was lower than expected.
在实验中,我们观察到爆炸温度低于预期。
3.The safety data sheet provided information about the detonating temperature of the substance.
安全数据表提供了关于该物质的爆炸温度的信息。
4.Proper storage conditions are essential to maintain the detonating temperature of the material.
适当的储存条件对维持材料的爆炸温度至关重要。
5.The chemical compound has a specific detonating temperature that must not be exceeded to prevent an explosion.
该化合物具有特定的爆炸温度,必须不超过以防止爆炸。
作文
The concept of detonating temperature refers to the specific temperature at which a substance can spontaneously ignite and produce a detonation. This phenomenon is particularly relevant in the fields of chemistry and materials science, where understanding the behavior of various compounds under different conditions is crucial for safety and efficiency. In this essay, I will explore the significance of detonating temperature, its implications in real-world applications, and how it impacts various industries.Firstly, it is essential to understand what causes a substance to reach its detonating temperature. Generally, when a material is heated, its molecules gain energy, which can lead to increased reactivity. At a certain point, known as the detonating temperature, the energy is sufficient to overcome the activation energy barrier, allowing the reaction to proceed rapidly and uncontrollably. This can result in an explosion, making it critical for engineers and scientists to identify and manage these temperatures in their work.In the context of explosives, the detonating temperature is a vital parameter. For instance, in military applications, understanding the detonating temperature of various explosives allows for the safe handling, storage, and deployment of these materials. If an explosive is exposed to temperatures above its detonating temperature, it could lead to catastrophic consequences. Therefore, rigorous testing and adherence to safety protocols are necessary to mitigate risks associated with accidental detonations.Moreover, the concept of detonating temperature extends beyond explosives. In the petrochemical industry, the production and refining of fuels also require careful consideration of detonating temperature. Fuels must be stored and transported within specific temperature ranges to prevent any risk of ignition. Understanding the detonating temperature of various fuels can help in designing safer storage facilities and transportation methods, ultimately reducing the likelihood of accidents and ensuring public safety.Additionally, the role of detonating temperature is crucial in environmental science, particularly concerning combustion processes. When fossil fuels are burned, the temperature of the combustion chamber must be managed to avoid reaching the detonating temperature of combustible gases. If these gases ignite too quickly, it can lead to incomplete combustion, resulting in harmful emissions and reduced energy efficiency. Therefore, engineers strive to optimize combustion systems to operate below the detonating temperature while maximizing energy output and minimizing environmental impact.In conclusion, the detonating temperature is a critical concept that plays an essential role in various scientific and industrial applications. From explosives to fuel production and environmental management, understanding and controlling the detonating temperature can significantly enhance safety and efficiency. As technology continues to advance, ongoing research into the properties of materials will further improve our ability to predict and manage detonating temperature, paving the way for safer practices across multiple sectors.
“爆轰温度”这一概念指的是一种物质能够自发点燃并产生爆炸的特定温度。这个现象在化学和材料科学领域尤为重要,因为在不同条件下理解各种化合物的行为对于安全性和效率至关重要。在这篇文章中,我将探讨“爆轰温度”的重要性,其在现实应用中的影响,以及它如何影响各个行业。首先,了解导致物质达到其“爆轰温度”的原因是必要的。通常,当一种材料被加热时,其分子会获得能量,这可能导致反应性增加。在某一点,即“爆轰温度”,能量足以克服活化能障碍,使反应迅速且不受控制地进行。这可能导致爆炸,因此工程师和科学家必须识别和管理这些温度,以确保工作安全。在爆炸物的背景下,“爆轰温度”是一个至关重要的参数。例如,在军事应用中,了解各种爆炸物的“爆轰温度”可以确保这些材料的安全处理、储存和部署。如果一种爆炸物暴露于高于其“爆轰温度”的温度,可能会导致灾难性的后果。因此,严格的测试和遵循安全协议是必要的,以减轻与意外爆炸相关的风险。此外,“爆轰温度”的概念超越了爆炸物。在石油化工行业,燃料的生产和精炼也需要仔细考虑“爆轰温度”。燃料必须在特定的温度范围内储存和运输,以防止任何点燃的风险。了解各种燃料的“爆轰温度”可以帮助设计更安全的储存设施和运输方式,从而最终减少事故发生的可能性,确保公众安全。此外,“爆轰温度”的作用在环境科学中也至关重要,尤其是在燃烧过程中。当化石燃料被燃烧时,必须管理燃烧室的温度,以避免达到可燃气体的“爆轰温度”。如果这些气体过快点燃,可能会导致不完全燃烧,从而产生有害排放并降低能源效率。因此,工程师努力优化燃烧系统,使其在“爆轰温度”以下运行,同时最大限度地提高能量输出并减少环境影响。总之,“爆轰温度”是一个关键概念,在各种科学和工业应用中发挥着重要作用。从爆炸物到燃料生产再到环境管理,理解和控制“爆轰温度”可以显著提高安全性和效率。随着技术的不断进步,对材料性质的持续研究将进一步改善我们预测和管理“爆轰温度”的能力,为多个行业的更安全实践铺平道路。
相关单词
