conduction holes

简明释义

导电空穴

英英释义

例句

1.The design of the circuit board includes several conduction holes to enhance electrical connectivity.

电路板的设计包含几个导通孔以增强电气连接性。

2.To improve signal integrity, the engineers added more conduction holes to the PCB layout.

为了提高信号完整性，工程师在PCB布局中增加了更多的导通孔。

3.The thermal management system relies on conduction holes for efficient heat dissipation.

热管理系统依赖于导通孔进行有效的热散失。

4.The presence of conduction holes can significantly affect the overall performance of the device.

存在的导通孔可以显著影响设备的整体性能。

5.In this experiment, we will measure the resistance across the conduction holes in the material.

在这个实验中，我们将测量材料中导通孔的电阻。

作文

In the realm of materials science, understanding the mechanisms of heat transfer is crucial for designing efficient thermal systems. One important concept in this field is the presence of conduction holes, which are specific areas within a material that allow for the conduction of heat. These conduction holes can significantly influence the thermal conductivity of the material, making it essential to study their properties and effects.When we think about heat transfer, we often imagine solid objects transferring heat through direct contact. However, in many materials, especially those that are porous or have complex structures, there are areas where heat can flow more easily. These areas are referred to as conduction holes. They can be microscopic voids or channels that facilitate the movement of thermal energy from one part of the material to another.The significance of conduction holes becomes evident when considering applications such as insulation materials, electronic devices, and even geological formations. For instance, in thermal insulators, the presence of conduction holes can either enhance or reduce the material's effectiveness at preventing heat loss. If these holes are strategically designed, they can trap air and minimize heat transfer, thereby improving insulation performance. Conversely, if the conduction holes are too large or poorly distributed, they may lead to unwanted heat conduction, compromising the material's insulating properties.In the context of electronics, conduction holes play a pivotal role in thermal management. As electronic devices generate heat during operation, effective heat dissipation is necessary to maintain optimal performance and prevent overheating. Engineers often design heat sinks with conduction holes to enhance the surface area available for heat transfer. By optimizing the size and distribution of these holes, engineers can create more efficient cooling solutions that prolong the lifespan of electronic components.Moreover, in geological studies, conduction holes can provide insights into the thermal properties of rocks and soils. Understanding how heat moves through these materials can help geologists assess geothermal energy potential and predict temperature changes in response to environmental factors. The presence of conduction holes in geological formations can indicate pathways for heat flow, which is critical for resource exploration and environmental assessments.In conclusion, conduction holes are vital components in the study of heat transfer within various materials. Their ability to facilitate or hinder thermal conductivity has significant implications across multiple fields, including materials science, electronics, and geology. By gaining a deeper understanding of these conduction holes, researchers and engineers can develop more effective thermal management strategies, improve material performance, and explore new avenues for energy efficiency. As technology continues to advance, the role of conduction holes will undoubtedly become even more prominent in the quest for sustainable solutions to our energy challenges.

在材料科学领域，理解热传递机制对于设计高效的热系统至关重要。一个重要的概念是材料内部存在的导热孔，这些特定区域允许热量的传导。这些导热孔可以显著影响材料的热导率，因此研究它们的属性和影响是必要的。当我们考虑热传递时，常常会想象固体物体通过直接接触传递热量。然而，在许多材料中，特别是那些多孔或具有复杂结构的材料中，存在一些区域能够更容易地传导热量。这些区域被称为导热孔。它们可以是微观的空隙或通道，促进热能从材料的一部分流向另一部分。导热孔的重要性在考虑绝缘材料、电子设备甚至地质构造等应用时变得显而易见。例如，在热绝缘体中，导热孔的存在可以增强或降低材料防止热量损失的效果。如果这些孔设计得当，它们可以捕获空气并最小化热传递，从而提高绝缘性能。相反，如果导热孔过大或分布不均，可能导致不必要的热传导，妨碍材料的绝缘特性。在电子学的背景下，导热孔在热管理中发挥着关键作用。由于电子设备在运行过程中产生热量，有效的散热是保持最佳性能和防止过热的必要条件。工程师通常设计带有导热孔的散热器，以增强可用于热传递的表面积。通过优化这些孔的大小和分布，工程师可以创建更有效的冷却解决方案，从而延长电子元件的使用寿命。此外，在地质研究中，导热孔可以提供岩石和土壤热性质的洞察。理解热量如何通过这些材料移动可以帮助地质学家评估地热能潜力，并预测环境因素对温度变化的影响。地质构造中导热孔的存在可以指示热流的路径，这对于资源勘探和环境评估至关重要。总之，导热孔是研究各种材料中热传递的重要组成部分。它们促进或阻碍热导率的能力对多个领域具有重要意义，包括材料科学、电子学和地质学。通过深入理解这些导热孔，研究人员和工程师可以开发更有效的热管理策略，提高材料性能，并探索能源效率的新途径。随着技术的不断进步，导热孔的作用无疑将在我们寻找可持续能源解决方案的过程中变得更加突出。