ramiform

简明释义

英[ˈræmɪfɔːm]美[ˈræməˌfɔrm]

adj. 有分枝的，枝状的

英英释义

单词用法

同义词

反义词

例句

1.According to action principle, extinguishing process and efficiency of the sprinkler systems, it is put forward that the ringed arrangements replace the ramiform arrangements.

根据自喷系统的作用原理、灭火过程和效率，提出用环状管网代替目前广泛采用的枝状管网的观点。

2.According to action principle, extinguishing process and efficiency of the sprinkler systems, it is put forward that the ringed arrangements replace the ramiform arrangements.

根据自喷系统的作用原理、灭火过程和效率，提出用环状管网代替目前广泛采用的枝状管网的观点。

3.We have been used to calculate the diameter of ringed piping according to ramiform piping, then it result in the bigger diameter and wasting of investment.

长期以来，习惯环状管网管径按枝状管网计算，管径偏大，造成浪费。

4.The scientist discovered a new species of coral that exhibited a unique ramiform 树枝状的 structure, making it stand out from others.

科学家发现了一种新的珊瑚物种，其独特的ramiform 树枝状的结构使其与其他物种不同。

5.In botany, the ramiform 树枝状的 growth pattern of certain plants allows for better sunlight absorption.

在植物学中，某些植物的ramiform 树枝状的生长模式有助于更好地吸收阳光。

6.The artist's sculpture featured ramiform 树枝状的 elements that mimicked the natural forms found in trees.

艺术家的雕塑中包含了模仿树木自然形态的ramiform 树枝状的元素。

7.During the hike, we noticed several ramiform 树枝状的 rock formations along the trail.

在徒步旅行中，我们注意到小径旁边有几处ramiform 树枝状的岩石形成。

8.The ramiform 树枝状的 design of the building allowed for more natural light to enter the interior spaces.

建筑的ramiform 树枝状的设计使得更多自然光能够进入室内空间。

作文

In the world of biology and botany, the term ramiform refers to structures that resemble or are shaped like branches. This concept is particularly significant when studying various plants and trees, as their growth patterns can provide insight into their adaptability and evolutionary processes. For instance, consider the way trees spread their limbs to capture sunlight. The ramiform architecture of a tree allows it to maximize photosynthesis by reaching out in multiple directions, much like a network of branches extending from a central trunk. This branching structure not only supports the tree's weight but also enhances its ability to survive in competitive environments where light is scarce. Moreover, the ramiform design is not exclusive to trees; it can also be observed in certain coral formations in marine ecosystems. Corals often develop ramiform structures that mimic the appearance of branches, which serve to increase their surface area for capturing nutrients from water currents. This adaptation is crucial for their survival, as it allows them to thrive in nutrient-poor waters while providing habitat for numerous marine species. The application of the ramiform concept extends beyond natural sciences. In architecture, for example, designers often draw inspiration from nature's ramiform forms to create buildings that harmonize with their surroundings. These designs can evoke feelings of tranquility and connection to nature, as they mimic the organic shapes found in forests and coastal regions. By incorporating ramiform elements into urban spaces, architects promote biodiversity and encourage a sense of community among residents. Furthermore, the ramiform principle can be applied in technology, particularly in the development of networks and systems. For instance, computer networks often utilize a ramiform topology to enhance connectivity and efficiency. Just as branches extend from a tree trunk, data pathways can branch out from a central server, allowing for more effective communication between devices. This ramiform approach ensures that information flows smoothly and reduces the risk of bottlenecks in data transmission. In conclusion, the term ramiform encapsulates a fundamental aspect of nature's design, highlighting the importance of branching structures in various contexts. From the resilience of trees and corals to the innovative applications in architecture and technology, the ramiform concept serves as a reminder of the interconnectedness of all living things and the potential for creative solutions inspired by nature. Understanding this term enriches our appreciation of the natural world and encourages us to look for similar patterns in our own lives, fostering a deeper connection to the environment around us.

在生物学和植物学的世界中，术语ramiform指的是类似或形状像树枝的结构。这个概念在研究各种植物和树木时尤其重要，因为它们的生长模式可以提供关于它们适应性和进化过程的见解。例如，考虑树木如何扩展其树枝以捕获阳光。树木的ramiform结构使其能够通过向多个方向伸展来最大化光合作用，就像一张从中央树干延伸出的分支网络。这种分支结构不仅支撑着树木的重量，还增强了它在光线稀缺的竞争环境中生存的能力。 此外，ramiform设计并不限于树木；在海洋生态系统中也可以观察到某些珊瑚形成的ramiform结构。珊瑚通常发展出类似于树枝的ramiform结构，这有助于增加其捕获水流中营养物质的表面积。这种适应性对它们的生存至关重要，因为它使它们能够在营养贫乏的水域中繁荣，同时为众多海洋物种提供栖息地。 ramiform概念的应用超越了自然科学。在建筑领域，例如，设计师常常从自然的ramiform形式中汲取灵感，以创建与周围环境和谐共处的建筑。这些设计可以唤起宁静和与自然的连接感，因为它们模仿森林和沿海地区的有机形状。通过在城市空间中融入ramiform元素，建筑师促进了生物多样性，并鼓励居民之间的社区感。 此外，ramiform原则还可以应用于技术，特别是在网络和系统的发展中。例如，计算机网络通常利用ramiform拓扑来增强连接性和效率。就像树枝从树干延伸一样，数据路径可以从中央服务器分支出来，允许设备之间更有效的通信。这种ramiform方法确保信息流动顺畅，并减少数据传输中的瓶颈风险。 总之，术语ramiform概括了自然设计的一个基本方面，突显了各个上下文中分支结构的重要性。从树木和珊瑚的韧性到建筑和技术中的创新应用，ramiform概念提醒我们所有生命体的相互联系，以及从自然中获得灵感的创造性解决方案的潜力。理解这个术语丰富了我们对自然世界的欣赏，并鼓励我们在自己的生活中寻找类似的模式，从而加深与周围环境的联系。