ammonia gelatine dynamite

简明释义

铵胶炸药

英英释义

例句

1.The military tested ammonia gelatine dynamite in various explosive scenarios.

军方在各种爆炸场景中测试了氨明胶炸药。

2.The engineer explained how ammonia gelatine dynamite works during the demolition process.

工程师在拆除过程中解释了氨明胶炸药的工作原理。

3.When handling ammonia gelatine dynamite, safety precautions are crucial.

处理氨明胶炸药时，安全措施至关重要。

4.In mining, ammonia gelatine dynamite is preferred for its stability and effectiveness.

在采矿中，氨明胶炸药因其稳定性和有效性而受到青睐。

5.The construction crew used ammonia gelatine dynamite to safely demolish the old building.

施工队使用氨明胶炸药安全地拆除了旧建筑。

作文

The world of chemistry is filled with fascinating compounds and reactions that can lead to both beneficial and destructive outcomes. One particularly interesting combination is that of ammonia gelatine dynamite, a term that might raise eyebrows at first but is rooted in the history of explosives. To understand this term, we need to break it down into its components: ammonia, gelatine, and dynamite. Each plays a crucial role in the formulation of explosives that have been used in various industries, including construction and demolition.Ammonia, a colorless gas with a distinct pungent smell, is widely used in fertilizers and cleaning products. In the context of explosives, ammonia acts as a stabilizer and can enhance the overall performance of the explosive material. Its chemical properties allow it to react with other substances to create powerful explosive reactions. Gelatine, on the other hand, is a gelling agent derived from collagen. It is often used in cooking and food production, but its role in explosives is equally significant. When mixed with nitroglycerin, gelatine helps to stabilize the explosive, making it safer to handle and more effective when detonated. This combination results in what is commonly known as gelignite, which is a type of explosive that is more stable than traditional dynamite.Dynamite itself, invented by Alfred Nobel in the 19th century, revolutionized the field of explosives. It consists of nitroglycerin absorbed into an inert substance, allowing for safer handling and application. ammonia gelatine dynamite is essentially a variant of this explosive, utilizing ammonia and gelatine to create a more stable and powerful compound.The significance of ammonia gelatine dynamite extends beyond its chemical composition; it also highlights the advancements in safety and efficiency in the use of explosives. The development of such compounds has allowed for more controlled explosions, reducing the risks associated with handling and using explosives in various applications.In addition to construction and demolition, ammonia gelatine dynamite has found uses in mining, quarrying, and even in the military. The ability to create precise and powerful explosions has transformed these industries, enabling them to accomplish tasks that would be impossible with conventional methods. For instance, in mining, controlled blasts can help break rock formations while minimizing environmental impact.However, it is essential to recognize the potential dangers associated with explosives. The misuse of ammonia gelatine dynamite or any explosive material can lead to catastrophic consequences. Therefore, stringent regulations and safety protocols must be followed when handling and using these substances. Training and education are crucial for anyone working in fields that involve explosives to ensure that they understand the risks and responsibilities that come with their use.In conclusion, ammonia gelatine dynamite represents a remarkable intersection of chemistry and engineering. Its components—ammonia, gelatine, and dynamite—combine to create a powerful and stable explosive that has numerous applications across various industries. As we continue to explore the capabilities of such materials, it is vital to prioritize safety and responsible usage to harness their full potential without compromising public safety. Understanding the science behind explosives not only fosters innovation but also ensures that we can use these powerful tools responsibly and effectively in our modern world.

化学世界充满了迷人的化合物和反应，这些反应可以导致有益或破坏性的结果。其中一个特别有趣的组合是氨明胶炸药，这个词乍一看可能让人 raised eyebrows，但它根植于爆炸物的历史。要理解这个术语，我们需要将其分解为几个组成部分：氨、明胶和炸药。每个成分在各种行业（包括建筑和拆除）中使用的炸药配方中都起着至关重要的作用。氨是一种无色气体，具有明显的刺鼻气味，广泛用于化肥和清洁产品。在爆炸物的背景下，氨作为稳定剂，并能增强爆炸物的整体性能。其化学性质使其能够与其他物质反应，产生强大的爆炸反应。另一方面，明胶是一种从胶原蛋白中提取的凝胶剂。它常用于烹饪和食品生产，但在爆炸物中的作用同样重要。当与甘油炸药混合时，明胶有助于稳定爆炸物，使其更安全地处理，更有效地引爆。这种组合产生了通常被称为明胶炸药的炸药，它比传统炸药更稳定。炸药本身由阿尔弗雷德·诺贝尔在19世纪发明，彻底改变了爆炸物领域。它由吸附在惰性物质上的甘油炸药组成，允许更安全的处理和应用。氨明胶炸药 本质上是这种炸药的一种变体，利用氨和明胶来创造一种更稳定、更强大的化合物。氨明胶炸药 的重要性不仅仅在于其化学成分；它还突显了在爆炸物使用中的安全性和效率的进步。这类化合物的发展使得爆炸更具控制性，从而降低了与在各种应用中处理和使用爆炸物相关的风险。除了建筑和拆除外，氨明胶炸药 还在采矿、采石甚至军事中找到了用途。创造精确而强大的爆炸的能力已经改变了这些行业，使他们能够完成用传统方法无法完成的任务。例如，在采矿中，控制爆炸可以帮助打破岩石层，同时最大限度地减少对环境的影响。然而，必须认识到与爆炸物相关的潜在危险。误用氨明胶炸药 或任何爆炸物都可能导致灾难性的后果。因此，在处理和使用这些物质时，必须遵循严格的法规和安全协议。培训和教育对于任何在涉及爆炸物的领域工作的人来说都是至关重要的，以确保他们理解使用这些物质所带来的风险和责任。总之，氨明胶炸药 代表了化学和工程的惊人交集。其成分——氨、明胶和炸药——结合在一起，创造出一种强大而稳定的炸药，在各个行业中有着众多应用。随着我们继续探索此类材料的能力，优先考虑安全和负责任的使用至关重要，以充分利用其潜力，而不危害公共安全。理解爆炸物背后的科学不仅促进了创新，还确保我们能够在现代世界中以负责任和有效的方式使用这些强大的工具。