low temperature breakdown

简明释义

低温损坏内部损坏

英英释义

例句

1.The engineer explained that the device is susceptible to low temperature breakdown 低温失效 during extreme winter conditions.

工程师解释说，该设备在极端冬季条件下容易发生低温失效。

2.To prevent low temperature breakdown 低温失效, we need to store the materials in a controlled environment.

为了防止低温失效，我们需要将材料存放在受控环境中。

3.The maintenance manual warns about the risks of low temperature breakdown 低温失效 for electronic components.

维护手册警告电子元件面临低温失效的风险。

4.In cold climates, manufacturers must consider low temperature breakdown 低温失效 when designing products.

在寒冷气候中，制造商在设计产品时必须考虑低温失效。

5.The research team conducted tests to measure the effects of low temperature breakdown 低温失效 on battery performance.

研究小组进行了测试，以测量低温失效对电池性能的影响。

作文

In various scientific and engineering fields, understanding the concept of low temperature breakdown is essential for ensuring the reliability and safety of materials and systems. Low temperature breakdown refers to the failure or degradation of materials when exposed to low temperatures, often resulting in reduced performance or catastrophic failure. This phenomenon can occur in several contexts, including electronics, structural materials, and biological systems. For example, in the field of electronics, many components are designed to operate within a specific temperature range. When temperatures drop below this range, the materials used in these components may become brittle or lose their electrical conductivity. This can lead to a low temperature breakdown of the circuit, causing devices to malfunction or fail altogether. Engineers must consider these factors when designing electronic devices that are intended to function in cold environments, such as satellites or outdoor sensors. Similarly, in construction and civil engineering, materials like concrete and steel have specific temperature tolerances. When exposed to extreme cold, these materials can experience a low temperature breakdown, leading to cracks, structural weaknesses, or even complete failure of buildings and infrastructure. To mitigate these risks, engineers often use additives or special techniques to enhance the performance of materials in low-temperature conditions. Biologically, low temperature breakdown can also have significant implications. For instance, certain enzymes and proteins in living organisms can become inactive or denatured at low temperatures, affecting metabolic processes and overall organism health. This is particularly relevant in the context of food preservation and storage, where maintaining an appropriate temperature is crucial to prevent spoilage and maintain nutritional value. Understanding low temperature breakdown is not only important for scientists and engineers but also for industries that rely on temperature-sensitive materials and products. The aerospace industry, for example, must account for the effects of low temperatures on materials used in aircraft and spacecraft. As these vehicles ascend into the atmosphere, they encounter drastic temperature changes that can lead to low temperature breakdown if not properly managed. In conclusion, the concept of low temperature breakdown is critical across various disciplines, from electronics to civil engineering and biology. Recognizing the potential for material degradation at low temperatures allows professionals to implement strategies that enhance durability and performance. By addressing the challenges associated with low temperature breakdown, we can ensure the safety and reliability of our technologies and infrastructures in extreme conditions. This knowledge is vital for advancing innovation and improving the quality of life in a world that increasingly demands resilience against environmental extremes.

在各个科学和工程领域，理解“低温失效”这一概念对于确保材料和系统的可靠性与安全性至关重要。“低温失效”是指材料在暴露于低温环境时发生的故障或降解，通常导致性能降低或灾难性故障。这种现象可以在多个领域中发生，包括电子学、结构材料和生物系统。 例如，在电子学领域，许多组件被设计为在特定温度范围内工作。当温度降到这个范围以下时，所用材料可能变得脆弱或失去电导性。这可能导致电路的低温失效，导致设备故障或完全失效。工程师在设计打算在寒冷环境中运行的电子设备（如卫星或户外传感器）时，必须考虑这些因素。 同样，在建筑和土木工程中，混凝土和钢铁等材料具有特定的温度耐受性。当暴露于极端寒冷时，这些材料可能会经历低温失效，导致裂缝、结构弱点，甚至建筑物和基础设施的完全失效。为了减轻这些风险，工程师通常使用添加剂或特殊技术来增强材料在低温条件下的性能。 在生物学上，“低温失效”也可能产生重大影响。例如，某些酶和蛋白质在低温下可能变得不活跃或变性，从而影响代谢过程和整体生物体健康。这在食品保存和储存的背景下尤其相关，在这里保持适当的温度对于防止腐败和保持营养价值至关重要。 理解低温失效不仅对科学家和工程师重要，而且对依赖温度敏感材料和产品的行业也至关重要。例如，航空航天工业必须考虑低温对飞机和航天器材料的影响。当这些飞行器升入大气层时，它们会遇到剧烈的温度变化，如果管理不当，可能导致低温失效。 总之，低温失效的概念在各个学科中都至关重要，从电子学到土木工程再到生物学。认识到低温下材料降解的潜力使专业人士能够实施增强耐久性和性能的策略。通过解决与低温失效相关的挑战，我们可以确保在极端条件下技术和基础设施的安全性和可靠性。这一知识对于推动创新和改善生活质量至关重要，因为我们的世界越来越需要抵御环境极端情况的能力。