axis of dilatation

简明释义

1. 膨胀轴; 2. 展开轴; 3. 扩大轴线;

英英释义

例句

1.The architect designed the building with an axis of dilatation to accommodate temperature changes.

建筑师设计了一个带有膨胀轴的建筑，以适应温度变化。

2.The engineer calculated the axis of dilatation to ensure the bridge could expand without damage.

工程师计算了膨胀轴以确保桥梁在扩展时不会受损。

3.During the experiment, we measured the axis of dilatation to assess the thermal expansion of the material.

在实验中，我们测量了膨胀轴以评估材料的热膨胀。

4.The axis of dilatation is essential in the design of pipelines to prevent bursting under pressure.

在管道设计中，膨胀轴是防止在压力下爆裂的关键。

5.In thermal analysis, understanding the axis of dilatation is crucial for predicting material behavior.

在热分析中，理解膨胀轴对预测材料行为至关重要。

作文

The concept of the axis of dilatation is fundamental in various fields, especially in physics and engineering. It refers to an imaginary line around which an object expands or contracts. When materials are subjected to temperature changes, they tend to either expand or contract depending on the heat applied. Understanding this behavior is crucial for engineers who design structures that must withstand varying temperatures. For example, bridges and railways are built with materials that can tolerate significant thermal expansion. The axis of dilatation helps engineers determine how much a material will expand and where the stress points will occur during this process.In practical applications, the axis of dilatation can influence the design of many everyday objects. Take, for instance, the manufacturing of metal pipes. If a pipe is heated, it will expand along its length, and the axis of dilatation will be the central line running through the length of the pipe. Engineers must account for this expansion when designing piping systems to prevent leaks or bursts that may occur due to excessive pressure from thermal expansion.Moreover, the axis of dilatation plays a significant role in geology, particularly in understanding how rocks and minerals respond to changes in temperature and pressure. As the earth's crust experiences tectonic movements, certain areas may undergo dilation, which can lead to earthquakes. By studying the axis of dilatation, geologists can predict potential shifts in the earth’s surface and implement safety measures in areas prone to seismic activity.In the realm of thermodynamics, the axis of dilatation is also relevant when discussing the behavior of gases. When gas is heated, it expands, and the axis of dilatation becomes crucial in determining how the gas molecules move and interact. This understanding is vital in designing engines and other systems that rely on gas expansion for operation. For instance, in internal combustion engines, the expansion of gases along a specific axis of dilatation contributes to the force that drives the pistons, ultimately powering the vehicle.Furthermore, the axis of dilatation is not limited to physical sciences; it also finds its application in fields like art and architecture. Artists and architects often consider how materials will behave under different conditions. For example, when constructing a glass facade for a building, the axis of dilatation is taken into account to ensure that the glass will not shatter due to temperature fluctuations. This careful consideration allows for aesthetically pleasing designs that are also structurally sound.In conclusion, the axis of dilatation is a vital concept that transcends various disciplines. Its implications are seen in engineering, geology, thermodynamics, and even art. By understanding how materials expand and contract around this imaginary line, professionals can create safer, more efficient designs that stand the test of time. As technology advances, the importance of mastering the principles surrounding the axis of dilatation will only grow, leading to innovations that improve our daily lives and enhance our understanding of the natural world.

“膨胀轴”这一概念在多个领域中都至关重要，尤其是在物理学和工程学中。它指的是一个假想的线，围绕这个线，一个物体会膨胀或收缩。当材料受到温度变化的影响时，它们往往会根据施加的热量而膨胀或收缩。理解这种行为对设计必须承受不同温度的结构的工程师至关重要。例如，桥梁和铁路是用能够承受显著热膨胀的材料建造的。膨胀轴帮助工程师确定材料将膨胀多少以及在此过程中应力点会出现在哪里。在实际应用中，膨胀轴可以影响许多日常物品的设计。例如，在金属管道的制造中。如果管道被加热，它将沿其长度膨胀，膨胀轴将是贯穿管道长度的中心线。工程师必须在设计管道系统时考虑这种膨胀，以防止因热膨胀产生过高压力而导致的泄漏或爆裂。此外，膨胀轴在地质学中也发挥着重要作用，特别是在理解岩石和矿物如何响应温度和压力变化方面。当地壳经历构造运动时，某些区域可能会发生膨胀，这可能导致地震。通过研究膨胀轴，地质学家可以预测地球表面的潜在变动，并在易发生地震的地区实施安全措施。在热力学领域，膨胀轴在讨论气体行为时也很相关。当气体被加热时，它会膨胀，而膨胀轴在确定气体分子如何移动和相互作用方面变得至关重要。这种理解对于设计依赖于气体膨胀进行运作的发动机和其他系统至关重要。例如，在内燃机中，气体沿特定的膨胀轴的膨胀为驱动活塞提供了力量，最终推动车辆前进。此外，膨胀轴不仅限于物理科学；它还在艺术和建筑等领域找到了应用。艺术家和建筑师通常会考虑材料在不同条件下的行为。例如，在为建筑物构建玻璃外立面时，会考虑膨胀轴，以确保玻璃不会因温度波动而破裂。这种细致的考虑使得美观的设计与结构的稳固性得以兼顾。总之，膨胀轴是一个跨越多个学科的重要概念。它的影响在工程、地质学、热力学甚至艺术中都能看到。通过理解材料如何围绕这一假想线膨胀和收缩，专业人员可以创造出更安全、更高效的设计，经得起时间的考验。随着技术的进步，掌握围绕膨胀轴的原理的重要性只会增加，从而带来改善我们日常生活的创新，增强我们对自然世界的理解。