parameter of materials

简明释义

物料参数

英英释义

例句

1.The engineer adjusted the parameter of materials to improve the product's durability.

工程师调整了材料参数以提高产品的耐用性。

2.The parameter of materials includes density, elasticity, and thermal conductivity.

材料的参数包括密度、弹性和热导率。

3.In our research, we analyzed the parameter of materials to enhance energy efficiency.

在我们的研究中，我们分析了材料参数以提高能源效率。

4.The parameter of materials affects how well the structure can withstand environmental stress.

材料的参数影响结构抵御环境压力的能力。

5.Understanding the parameter of materials is crucial for selecting the right components in construction.

理解材料参数对于选择建筑中合适的组件至关重要。

作文

In the field of materials science, understanding the parameter of materials is crucial for engineers and scientists alike. These parameters define the characteristics and behaviors of different materials under various conditions. They include properties such as tensile strength, thermal conductivity, electrical resistivity, and many others. Each of these parameters plays a significant role in determining how a material will perform in specific applications.For instance, when designing a bridge, engineers must consider the tensile strength of the materials they choose. The parameter of materials related to tensile strength indicates how much force a material can withstand while being stretched or pulled before it breaks. This is essential because a bridge must support not only its own weight but also the weight of vehicles and pedestrians. If the wrong materials are selected, the bridge could fail, leading to catastrophic consequences.Moreover, thermal conductivity is another important parameter of materials. It measures a material's ability to conduct heat. In applications such as insulation, choosing a material with low thermal conductivity is vital to prevent heat loss in buildings. On the other hand, for heat exchangers, materials with high thermal conductivity are preferred to maximize heat transfer efficiency. Understanding these parameters allows engineers to select the right materials that meet the thermal requirements of their designs.Electrical resistivity is yet another parameter of materials that is critical in the electronics industry. It determines how well a material can conduct electricity. Conductors, such as copper, have low electrical resistivity, making them ideal for wiring and electronic components. Conversely, insulators, like rubber, have high electrical resistivity, preventing the flow of electric current. Selecting materials based on their electrical resistivity is essential for ensuring safety and functionality in electrical applications.The parameter of materials can also influence environmental considerations. For example, biodegradable materials are gaining popularity due to their lower environmental impact compared to traditional plastics. Understanding the parameters of these materials, such as degradation rate and mechanical properties, helps manufacturers create products that are both functional and environmentally friendly.In recent years, advancements in technology have allowed for more precise measurement and manipulation of the parameter of materials. Techniques such as nanotechnology enable scientists to engineer materials at the molecular level, resulting in enhanced properties that were previously unattainable. This opens up new possibilities for innovation across various industries, from aerospace to medical devices.In conclusion, the parameter of materials encompasses a wide range of properties that are essential for the design and application of materials in engineering and technology. By understanding these parameters, professionals can make informed decisions that lead to safer, more efficient, and sustainable products. As we continue to explore new materials and technologies, the significance of these parameters will only grow, shaping the future of engineering and material science.

在材料科学领域，理解材料参数对工程师和科学家来说至关重要。这些参数定义了不同材料在各种条件下的特性和行为。它们包括拉伸强度、热导率、电阻率等许多属性。每一个这些参数在确定材料在特定应用中的表现方面都起着重要作用。例如，在设计桥梁时，工程师必须考虑所选材料的拉伸强度。与拉伸强度相关的材料参数指示了材料在被拉伸或拉扯时能够承受多少力而不破裂。这是至关重要的，因为一座桥不仅必须支撑自身的重量，还必须支撑车辆和行人的重量。如果选择错误的材料，桥梁可能会失败，导致灾难性的后果。此外，热导率是另一个重要的材料参数。它测量材料传导热量的能力。在绝缘应用中，选择低热导率的材料对于防止建筑物的热量损失至关重要。另一方面，对于热交换器，优选高热导率的材料，以最大化热传递效率。理解这些参数使工程师能够选择符合其设计热要求的合适材料。电阻率也是在电子行业中至关重要的材料参数。它决定了材料导电的能力。导体，如铜，具有低电阻率，使其成为布线和电子元件的理想选择。相反，绝缘体，如橡胶，具有高电阻率，防止电流的流动。根据电阻率选择材料对于确保电气应用的安全性和功能性至关重要。材料参数还可以影响环境考虑。例如，生物可降解材料因其较低的环境影响而受到越来越多的欢迎，与传统塑料相比。了解这些材料的参数，如降解速率和机械性能，有助于制造商创造既实用又环保的产品。近年来，技术的进步使得对材料参数的更精确测量和操控成为可能。纳米技术等技术使科学家能够在分子层面上设计材料，从而产生以前无法实现的增强性能。这为航空航天到医疗设备等各个行业的创新开辟了新的可能性。总之，材料参数涵盖了一系列对材料设计和应用至关重要的属性。通过理解这些参数，专业人士可以做出明智的决策，从而导致更安全、更高效和可持续的产品。随着我们继续探索新材料和技术，这些参数的重要性只会增加，塑造工程和材料科学的未来。