anticlastic
简明释义
英[ˌæntɪˈklæstɪk]美[ˌæntɪˈklæstɪk]
adj. [数] 互反的;[数] 鞍形面的
英英释义
Relating to a surface that curves in opposite directions, typically forming a saddle shape. | 指一种曲面,沿相反方向弯曲,通常形成鞍形。 |
单词用法
同义词
反义词
| 同曲面 | The roof design is synclastic, curving upwards in a uniform manner. | 这个屋顶设计是同曲面,均匀向上弯曲。 | |
| 凹面 | 凹透镜用于发散光线。 |
例句
1.The paper introduces the anticlastic and water-tight performance of low content polypropylene fiber concrete.
本文介绍了低含量聚丙烯纤维混凝土的抗弹性和防水性能。
2.The paper introduces the anticlastic and water-tight performance of low content polypropylene fibre concrete.
文章介绍了低掺率聚丙烯纤维混凝土的抗裂和抗渗性能。
3.The paper introduces the anticlastic and water-tight performance of low content polypropylene fibre concrete.
文章介绍了低掺率聚丙烯纤维混凝土的抗裂和抗渗性能。
4.In mathematics, an anticlastic surface can be described as having a negative Gaussian curvature.
在数学中,一个反曲面可以被描述为具有负高斯曲率。
5.When studying the properties of materials, we found that the anticlastic structure enhances strength.
在研究材料特性时,我们发现反曲结构增强了强度。
6.The sculpture features an anticlastic form that creates interesting shadows.
这座雕塑呈现出一种反曲形状,产生有趣的阴影。
7.The designer used an anticlastic approach to create a unique piece of furniture.
设计师采用了反曲的方法来创造一件独特的家具。
8.The architect designed an anticlastic roof that curves downward on both sides.
建筑师设计了一个反曲的屋顶,双侧向下弯曲。
作文
In the world of architecture and design, the term anticlastic refers to a surface that curves in opposite directions. This concept is not only fascinating but also plays a significant role in creating structures that are both aesthetically pleasing and structurally sound. To understand the importance of anticlastic surfaces, one must first appreciate the fundamentals of curvature in design. Curved surfaces can be classified into two main categories: synclastic and anticlastic. Synclastic surfaces curve in the same direction, like the exterior of a sphere, while anticlastic surfaces exhibit a more complex behavior, resembling a saddle shape where one axis curves upwards and the other downwards.The application of anticlastic surfaces can be seen in various architectural masterpieces around the globe. One of the most notable examples is the famous Guggenheim Museum in Bilbao, Spain, designed by Frank Gehry. The building's flowing, organic shapes showcase the beauty and functionality of anticlastic forms. The interplay of light and shadow on these surfaces creates an ever-changing visual experience for visitors, demonstrating how anticlastic designs can enhance the overall aesthetic appeal of a structure.Moreover, anticlastic surfaces are not limited to just large-scale architecture; they also find their way into smaller designs, such as furniture and product design. For instance, chairs with anticlastic elements can provide better ergonomic support, allowing for a more comfortable seating experience. Designers often use this principle to create innovative products that combine form and function seamlessly.In addition to aesthetics and comfort, anticlastic surfaces also have practical advantages in engineering. Structures that incorporate these types of surfaces can distribute loads more evenly, which contributes to their stability and durability. This is particularly important in the construction of bridges and roofs, where the ability to withstand various forces is crucial. Engineers and architects who understand the significance of anticlastic geometry can create safer and more efficient designs.Furthermore, the study of anticlastic forms extends beyond physical structures; it also influences art and sculpture. Artists often explore the concept of curvature in their work, using anticlastic shapes to evoke emotions and challenge perceptions. The dynamic nature of these forms can lead to a deeper engagement with the viewer, as they navigate the complexities of the artwork.In conclusion, the term anticlastic encompasses a wide range of applications in architecture, engineering, and art. By understanding the principles behind anticlastic surfaces, designers and engineers can push the boundaries of creativity and innovation. As we continue to explore the potential of these unique forms, it becomes clear that anticlastic geometry is not merely a technical concept but a vital element that enriches our built environment and artistic expressions. The future of design will undoubtedly benefit from a deeper appreciation of the beauty and functionality that anticlastic surfaces offer.
在建筑和设计的世界中,术语anticlastic指的是朝相反方向弯曲的表面。这个概念不仅令人着迷,而且在创造既美观又结构坚固的建筑方面发挥着重要作用。要理解anticlastic表面的重要性,首先必须欣赏设计曲率的基本原理。曲面可以分为两大类:同曲面和anticlastic表面。同曲面朝同一方向弯曲,就像球体的外表,而anticlastic表面则表现出更复杂的行为,类似于鞍形,其中一个轴向向上弯曲,另一个向下弯曲。anticlastic表面的应用可在全球各地的建筑杰作中看到。其中一个最显著的例子是西班牙毕尔巴鄂的古根海姆博物馆,由弗兰克·盖里设计。建筑流畅、有机的形状展示了anticlastic形式的美丽和功能性。这些表面上光与影的相互作用为游客创造了一种不断变化的视觉体验,展示了anticlastic设计如何增强建筑的整体美感。此外,anticlastic表面不仅限于大型建筑;它们还出现在较小的设计中,例如家具和产品设计。例如,具有anticlastic元素的椅子可以提供更好的人体工程学支持,使坐姿更加舒适。设计师常常利用这一原理创造出将形式和功能无缝结合的创新产品。除了美学和舒适性之外,anticlastic表面在工程学上也具有实际优势。 Incorporating这些类型的表面的结构可以更均匀地分配负载,这有助于其稳定性和耐久性。这在桥梁和屋顶的建造中特别重要,因为承受各种力量的能力至关重要。理解anticlastic几何的重要性的工程师和建筑师可以创造出更安全、更高效的设计。此外,对anticlastic形式的研究超越了物理结构;它也影响了艺术和雕塑。艺术家们常常在他们的作品中探索曲率的概念,使用anticlastic形状来唤起情感并挑战观众的感知。这些形状的动态特性可以使观众更深入地参与其中,因为他们在艺术作品的复杂性中徘徊。总之,术语anticlastic涵盖了建筑、工程和艺术中的广泛应用。通过理解anticlastic表面的原理,设计师和工程师可以突破创造力和创新的界限。随着我们继续探索这些独特形式的潜力,显然anticlastic几何不仅仅是一个技术概念,而是丰富我们建筑环境和艺术表现的重要元素。设计的未来无疑将从对anticlastic表面所提供的美丽和功能的更深刻理解中受益。
