hyperstatic

简明释义

英[/ˌhaɪpərˈstætɪk/]美[/ˌhaɪpərˈstætɪk/]

adj. 超静定的；超稳定的

英英释义

单词用法

同义词

反义词

例句

1.On the basis of relevant theory of hyperstatic structure in structural mechanism, the paper discusses the mechanism of secondary interior force caused by prestressing and its effect on structures.

基于结构力学中超静定结构的相关理论，讨论了预应力次内力产生的机理及其对结构的影响，进而提出合理利用次内力的设计思想。

2.On the basis of relevant theory of hyperstatic structure in structural mechanism, the paper discusses the mechanism of secondary interior force caused by prestressing and its effect on structures.

基于结构力学中超静定结构的相关理论，讨论了预应力次内力产生的机理及其对结构的影响，进而提出合理利用次内力的设计思想。

3.By theoretical analysis, the considerations were put forward about the check with symmetry solving hyperstatic structure, avoiding internal force diagram check errors caused by inertial thinking.

通过理论分析，提出利用对称性求解超静定结构时应注意的问题，避免因惯性思维造成最后内力图校核出现错。

4.Multichambered Thin-walled box girder is a hyperstatic structure, it is a difficulty to solve its hyperstatic unknown shearing flow.

多室薄壁箱梁是超静定结构，求解其超静定未知剪力流是一个难点。

5.Numerical calculation to the temperature field of structural member and hyperstatic structure was also carried.

对高温下建筑构件及超静定结构温度场进行了数值计算。

6.However, As the whole structure is hyperstatic, it is very difficult to calculate the results.

但是，由于整个结构是超静定的，计算困难。

7.In advanced mechanics, a structure is considered hyperstatic 超静定的 when it has more supports than necessary.

在高级力学中，当一个结构的支撑超过必要数量时，它被认为是hyperstatic 超静定的。

8.The analysis of hyperstatic 超静定的 systems often requires complex mathematics.

对hyperstatic 超静定的系统的分析通常需要复杂的数学知识。

9.Engineers must consider hyperstatic 超静定的 conditions when designing bridges to ensure stability.

工程师在设计桥梁时必须考虑hyperstatic 超静定的条件以确保稳定性。

10.A hyperstatic 超静定的 beam can distribute loads more efficiently than a simply supported beam.

与简单支撑梁相比，hyperstatic 超静定的梁可以更有效地分配荷载。

11.Understanding hyperstatic 超静定的 structures is crucial for civil engineering students.

理解hyperstatic 超静定的结构对土木工程学生至关重要。

作文

In the realm of engineering and physics, understanding the behavior of structures under various loads is crucial. One term that often arises in discussions of structural analysis is hyperstatic, which refers to a system that has more supports than are necessary to maintain equilibrium. This concept is fundamental in the study of statics and dynamics, as it helps engineers determine how structures will respond to external forces. A hyperstatic structure is characterized by its ability to distribute loads across multiple points, which can enhance stability but also complicate analysis. To illustrate the significance of hyperstatic systems, let's consider a simple example: a bridge. When designing a bridge, engineers must ensure that it can support the weight of vehicles and withstand environmental factors such as wind and earthquakes. If the bridge is hyperstatic, it means that there are additional supports or constraints beyond what is strictly necessary for the bridge to remain standing. While this might seem advantageous, it can lead to complexities in calculating internal forces and moments within the structure. The challenge with hyperstatic structures lies in their redundancy. While redundancy can provide safety, it can also make it difficult to predict how the structure will behave under load. For instance, if one support fails, the redistribution of forces can lead to unexpected results. Engineers must utilize advanced methods, such as finite element analysis, to accurately assess the performance of hyperstatic systems. This highlights the importance of thorough planning and analysis in engineering design. Moreover, hyperstatic structures can be beneficial in certain contexts. For example, in large buildings or complex frameworks, having multiple supports can prevent catastrophic failure. The additional supports can help manage deflections and vibrations, making the structure safer and more comfortable for occupants. However, the trade-off is that engineers must invest more time and resources into analyzing these structures to ensure they perform as intended. In conclusion, the term hyperstatic plays a vital role in the field of structural engineering. It encapsulates the idea of having more supports than necessary, which can lead to both advantages and challenges. As engineers continue to innovate and design increasingly complex structures, understanding the implications of hyperstatic systems will be essential for ensuring safety and reliability. By mastering this concept, future engineers can contribute to the development of robust infrastructures that stand the test of time.

在工程和物理学领域，理解结构在各种载荷下的行为至关重要。一个常常出现在结构分析讨论中的术语是超静定，它指的是一个系统具有比维持平衡所需的支持更多的支持。这个概念在静力学和动力学的研究中是基础，因为它帮助工程师确定结构如何响应外部力量。超静定结构的特点是能够将载荷分配到多个点，这可以增强稳定性，但也会使分析变得复杂。 为了说明超静定系统的重要性，让我们考虑一个简单的例子：桥梁。在设计桥梁时，工程师必须确保它能够支撑车辆的重量，并承受风和地震等环境因素。如果桥梁是超静定的，这意味着有额外的支持或约束，超出了桥梁保持直立所需的严格要求。虽然这看起来可能是有利的，但这可能导致计算内部力量和弯矩的复杂性。 超静定结构的挑战在于它们的冗余性。虽然冗余性可以提供安全性，但它也可能使预测结构在载荷下的行为变得困难。例如，如果一个支撑失效，力量的重新分配可能会导致意想不到的结果。工程师必须利用先进的方法，例如有限元分析，来准确评估超静定系统的性能。这突显了在工程设计中进行全面规划和分析的重要性。 此外，在某些情况下，超静定结构可能是有益的。例如，在大型建筑或复杂框架中，拥有多个支撑可以防止灾难性故障。额外的支撑可以帮助管理挠度和振动，使结构对居住者更安全、更舒适。然而，权衡之下，工程师必须投入更多的时间和资源来分析这些结构，以确保它们按预期运行。 总之，术语超静定在结构工程领域扮演着至关重要的角色。它概括了拥有比必要支持更多的支持的理念，这可能带来优势和挑战。随着工程师继续创新和设计日益复杂的结构，理解超静定系统的影响将对确保安全和可靠性至关重要。通过掌握这一概念，未来的工程师可以为开发经得起时间考验的坚固基础设施做出贡献。