temperature shrinkage

简明释义

温度收缩

英英释义

例句

1.The final product dimensions were affected by temperature shrinkage 温度收缩 after cooling.

冷却后，最终产品的尺寸受到温度收缩的影响。

2.During the cooling process, we observed significant temperature shrinkage 温度收缩 in the material.

在冷却过程中，我们观察到材料有显著的温度收缩。

3.To prevent defects, it is crucial to monitor temperature shrinkage 温度收缩 during the manufacturing process.

为了防止缺陷，在生产过程中监测温度收缩至关重要。

4.Understanding temperature shrinkage 温度收缩 helps improve the quality of the finished goods.

理解温度收缩有助于提高成品的质量。

5.The engineers accounted for temperature shrinkage 温度收缩 when designing the new components.

工程师在设计新组件时考虑了温度收缩。

作文

Understanding the concept of temperature shrinkage is essential in various fields, especially in materials science and engineering. Temperature shrinkage refers to the reduction in size or volume of a material as it cools down. This phenomenon can significantly affect the performance and durability of materials used in construction, manufacturing, and other industries. For instance, metals typically expand when heated and contract when cooled. This contraction is what we refer to as temperature shrinkage. It is crucial for engineers to account for this behavior when designing structures or components that will experience temperature fluctuations.In practical applications, temperature shrinkage can lead to several challenges. For example, when constructing buildings, if the materials used do not properly accommodate for temperature shrinkage, it can result in cracks and structural failures over time. This is particularly important in regions with extreme temperature variations. Engineers often use materials with low coefficients of thermal expansion to minimize the effects of temperature shrinkage in their designs.Moreover, temperature shrinkage is not limited to metals; it also affects polymers and composites. In the manufacturing of plastic products, for example, manufacturers must consider how cooling rates influence temperature shrinkage. If the cooling process is too rapid, it can cause warping or deformation in the final product. Therefore, controlling the cooling rate during production is vital to ensure the integrity of the product.The implications of temperature shrinkage extend beyond just physical dimensions. In electronics, for instance, components are often subjected to significant thermal cycling. The differential temperature shrinkage between different materials can lead to mechanical stresses that may compromise the reliability of electronic devices. Thus, understanding and mitigating temperature shrinkage is crucial for ensuring the longevity and functionality of electronic systems.Additionally, temperature shrinkage plays a role in the field of thermodynamics. When analyzing heat transfer processes, engineers need to consider how temperature shrinkage affects the overall efficiency of systems such as engines and refrigeration units. The ability to predict and manage temperature shrinkage can lead to improved designs that enhance performance and energy efficiency.In conclusion, temperature shrinkage is a fundamental concept that impacts many aspects of engineering and material science. From construction to manufacturing and electronics, understanding how materials respond to temperature changes is critical for creating reliable and durable products. As technology advances, the importance of managing temperature shrinkage will only grow, making it a vital area of study for future engineers and scientists. By incorporating knowledge of temperature shrinkage into design and manufacturing processes, we can create more resilient structures and devices that stand the test of time.

理解“温度收缩”这一概念在多个领域中至关重要，尤其是在材料科学和工程学中。“温度收缩”是指材料在冷却时尺寸或体积的减少。这一现象会显著影响建筑、制造及其他行业中材料的性能和耐用性。例如，金属通常在加热时膨胀，而在冷却时收缩。这种收缩就是我们所说的“温度收缩”。工程师在设计会经历温度波动的结构或组件时，必须考虑这种行为。在实际应用中，“温度收缩”可能导致一些挑战。例如，在建造建筑物时，如果所用材料未能妥善适应“温度收缩”，可能会导致裂缝和结构失效。尤其是在温差极大的地区，这一点尤为重要。工程师通常使用具有低热膨胀系数的材料，以最小化设计中“温度收缩”的影响。此外，“温度收缩”不仅限于金属；它还会影响聚合物和复合材料。在塑料产品的制造中，制造商必须考虑冷却速率如何影响“温度收缩”。如果冷却过程过快，可能会导致最终产品的翘曲或变形。因此，在生产过程中控制冷却速率对于确保产品的完整性至关重要。“温度收缩”的影响不仅限于物理尺寸。在电子产品中，例如，组件通常会经历显著的热循环。不同材料之间的“温度收缩”差异可能导致机械应力，从而可能危及电子设备的可靠性。因此，理解和减轻“温度收缩”对确保电子系统的持久性和功能至关重要。此外，“温度收缩”在热力学领域也发挥着作用。在分析热传递过程时，工程师需要考虑“温度收缩”如何影响系统（如发动机和制冷设备）的整体效率。能够预测和管理“温度收缩”可以改善设计，从而提高性能和能源效率。总之，“温度收缩”是一个基本概念，影响着工程和材料科学的许多方面。从建筑到制造再到电子产品，理解材料如何响应温度变化对于创造可靠和耐用的产品至关重要。随着技术的进步，管理“温度收缩”的重要性只会增加，这使其成为未来工程师和科学家研究的重要领域。通过将“温度收缩”的知识融入设计和制造过程中，我们可以创造出更加坚固的结构和设备，能够经受住时间的考验。