annular core

简明释义

环形铁心

英英释义

例句

1.During the experiment, we measured the temperature of the annular core 环形核心 to determine its thermal conductivity.

在实验过程中，我们测量了环形核心 annular core的温度以确定其热导率。

2.In the design of the new turbine, engineers focused on optimizing the annular core 环形核心 to improve efficiency.

在新涡轮机的设计中，工程师们专注于优化环形核心 annular core以提高效率。

3.The annular core 环形核心 of the transformer is essential for its electromagnetic properties.

变压器的环形核心 annular core对其电磁特性至关重要。

4.The annular core 环形核心 structure allows for better flow dynamics in fluid systems.

这种环形核心 annular core结构使流体系统中的流动动态更好。

5.The researchers discovered that the annular core 环形核心 of the earth's mantle plays a crucial role in seismic activity.

研究人员发现地球地幔的环形核心 annular core在地震活动中起着至关重要的作用。

作文

In the field of material science and engineering, the term annular core refers to a specific structural configuration that is characterized by a hollow center surrounded by a solid outer layer. This unique design has garnered significant attention due to its potential applications in various industries, including aerospace, electronics, and civil engineering. The annular core structure can enhance the mechanical properties of materials, making them lighter yet stronger, which is crucial in sectors where weight reduction is paramount without compromising strength.One of the primary advantages of an annular core design is its ability to provide excellent load-bearing capabilities. For instance, in aerospace engineering, components such as wings and fuselage sections are often designed using an annular core structure to minimize weight while maximizing strength and rigidity. This is particularly important in aircraft design, where every gram counts towards fuel efficiency and overall performance. By utilizing materials with an annular core, engineers can create parts that are not only lighter but also more durable under stress and strain.Moreover, the annular core configuration can also improve thermal and acoustic insulation properties. In construction, for example, walls and roofs designed with an annular core can better insulate against heat loss and sound transmission. This makes buildings more energy-efficient and comfortable for occupants. The air gap created by the annular core acts as a barrier that reduces the transfer of heat and sound, leading to improved living conditions and lower energy costs.In electronics, the annular core structure is often employed in the design of transformers and inductors. The magnetic properties of materials can be significantly enhanced by using an annular core, allowing for more efficient energy transfer. This is particularly beneficial in power supply systems where efficiency is critical. The use of an annular core in these applications can lead to smaller, lighter devices that do not sacrifice performance.The manufacturing process of creating an annular core structure can vary depending on the material and application. Techniques such as additive manufacturing, molding, and extrusion are commonly used to produce these components. Each method has its advantages and challenges, and the choice of technique often depends on the desired properties of the final product. For instance, additive manufacturing allows for complex geometries that can optimize the performance of the annular core, while traditional molding might be more cost-effective for mass production.In conclusion, the concept of the annular core plays a vital role in modern engineering and technology. Its ability to enhance mechanical properties, improve insulation, and increase efficiency makes it an invaluable design choice across various fields. As industries continue to innovate and push the boundaries of what is possible, understanding and utilizing structures like the annular core will undoubtedly lead to advancements that improve our daily lives and contribute to sustainable practices. The exploration of annular core applications is just beginning, and there is much potential for future developments that could revolutionize how we approach design and manufacturing in numerous sectors.

在材料科学和工程领域，术语annular core指的是一种特定的结构配置，其特点是中间为空心，外层为实心。这种独特的设计因其在航空航天、电子和土木工程等多个行业的潜在应用而受到了广泛关注。annular core结构可以增强材料的机械性能，使其更轻但更强，这在需要减轻重量而不妥协强度的领域至关重要。annular core设计的主要优点之一是其提供了出色的承载能力。例如，在航空航天工程中，机翼和机身部件通常采用annular core结构设计，以最小化重量，同时最大化强度和刚度。这在飞机设计中尤为重要，因为每克重量都直接影响燃油效率和整体性能。通过利用具有annular core的材料，工程师可以制造出不仅更轻而且在应力和应变下更耐用的部件。此外，annular core配置还可以改善热绝缘和声学隔离性能。例如，在建筑中，采用annular core设计的墙壁和屋顶可以更好地隔绝热量损失和声音传播。这使得建筑物更加节能，居住者更舒适。annular core所形成的空气间隙作为一种屏障，减少了热量和声音的传递，从而改善了居住条件并降低了能源成本。在电子产品中，annular core结构常用于变压器和电感器的设计。通过使用annular core，材料的磁性能可以显著增强，从而实现更高效的能量转移。这在电源系统中尤为有利，因为效率至关重要。在这些应用中使用annular core可以导致更小、更轻的设备，而不牺牲性能。制造annular core结构的过程可能会因材料和应用而异。增材制造、模具成型和挤出等技术通常用于生产这些组件。每种方法都有其优缺点，选择技术往往取决于最终产品的期望性能。例如，增材制造允许优化annular core性能的复杂几何形状，而传统模具可能在大规模生产中更具成本效益。总之，annular core的概念在现代工程和技术中发挥着重要作用。它增强机械性能、改善绝缘和提高效率的能力使其成为各个领域不可或缺的设计选择。随着各行业不断创新并突破可能性的界限，理解和利用像annular core这样的结构无疑将导致改善我们日常生活的进步，并促进可持续实践。对annular core应用的探索才刚刚开始，未来的发展潜力巨大，可能会彻底改变我们在众多领域的设计和制造方式。