tubulation

简明释义

英[ˌtjuːbəˈleɪʃən]美[ˌtʌbjəˈleɪʃən]

n. 制管；装管（焊管脚）

英英释义

单词用法

同义词

反义词

例句

1.This paper introduces in detail the thrust design and armored joint hydraulic test for PCCP restricted tubulation.

详细介绍了PCCP限制性管段止推设计和铠装接头水压试验的情况。

2.This paper introduces in detail the thrust design and armored joint hydraulic test for PCCP restricted tubulation.

详细介绍了PCCP限制性管段止推设计和铠装接头水压试验的情况。

3.In biology, tubulation can refer to the formation of tubular structures in cells.

在生物学中，管道化可以指细胞中管状结构的形成。

4.The tubulation process is critical in the manufacturing of pipes and tubes.

在管道和管子的制造中，管道化过程至关重要。

5.The engineer explained the process of tubulation to ensure proper fluid flow in the system.

工程师解释了管道化的过程，以确保系统中液体的正常流动。

6.The research focused on the tubulation of nanomaterials for drug delivery systems.

研究集中在纳米材料的管道化，用于药物递送系统。

7.During the experiment, we observed the tubulation of the polymer under certain conditions.

在实验过程中，我们观察到聚合物在特定条件下的管道化现象。

作文

In the world of science and engineering, various terms are used to describe phenomena that may not be immediately familiar to the general public. One such term is tubulation, which refers to the process or result of forming tubes or tubular structures. This concept is particularly relevant in fields like biology, where the formation of tubular organs or structures is a key aspect of development, and in engineering, where the creation of pipes and conduits is essential for fluid transport.The significance of tubulation can be observed in numerous applications. For example, in the medical field, understanding how blood vessels undergo tubulation during embryonic development helps researchers find ways to treat conditions related to vascular diseases. Scientists study the molecular mechanisms that drive this process, aiming to replicate it for therapeutic purposes. By investigating the genes and proteins involved in tubulation, they can develop strategies to promote healing or even engineer new blood vessels for patients suffering from chronic conditions.Similarly, in the realm of materials science, tubulation plays a crucial role in the development of lightweight yet strong materials. Engineers often design composite materials that incorporate tubular structures to enhance strength without significantly increasing weight. This approach is particularly beneficial in the aerospace industry, where minimizing weight while maximizing structural integrity is paramount. The ability to manipulate tubulation at the microscopic level allows for innovations that can lead to more efficient aircraft and spacecraft.Moreover, tubulation is also evident in environmental engineering, where the design of drainage systems and pipelines relies on the principles of tube formation. Properly designed tubulation systems ensure efficient water management and reduce the risk of flooding in urban areas. Engineers must consider factors such as flow rates, material properties, and the surrounding environment when creating these systems. Effective tubulation can lead to sustainable solutions that minimize environmental impact while meeting the needs of growing populations.Furthermore, tubulation is not limited to physical structures; it can also describe processes in data transmission and networking. In computer science, the concept of data packets being transmitted through 'tubes' in a network can be likened to tubulation. Understanding how data flows efficiently through networks is crucial for improving internet speeds and reliability. Network engineers work to optimize tubulation protocols, ensuring that data reaches its destination swiftly and securely.In conclusion, tubulation is a multifaceted term that encompasses various fields, highlighting the importance of tubular structures in both natural and engineered systems. Whether we are discussing biological processes, innovative materials, effective drainage systems, or efficient data transmission, the concept of tubulation remains integral to our understanding and advancement in these areas. As technology continues to evolve, the exploration of tubulation will undoubtedly lead to new discoveries and applications that benefit society as a whole.

在科学和工程的世界中，有许多术语用来描述可能对公众并不熟悉的现象。其中一个术语是tubulation，指的是形成管状或管道结构的过程或结果。这个概念在生物学等领域尤为相关，因为管状器官或结构的形成是发育的关键方面，而在工程学中，创建管道和导管对于流体运输至关重要。tubulation的重要性可以在许多应用中观察到。例如，在医学领域，理解血管在胚胎发育过程中如何经历tubulation有助于研究人员找到治疗与血管疾病相关的病症的方法。科学家研究驱动这一过程的分子机制，旨在为治疗目的复制它。通过调查参与tubulation的基因和蛋白质，他们可以制定促进愈合的策略，甚至为患有慢性病的患者工程出新的血管。同样，在材料科学领域，tubulation在轻质且强大的材料开发中发挥着关键作用。工程师经常设计包含管状结构的复合材料，以增强强度而不显著增加重量。这种方法在航空航天工业中特别有益，因为在最大化结构完整性的同时最小化重量至关重要。在微观层面上操控tubulation的能力使得能够进行创新，从而导致更高效的飞机和航天器。此外，tubulation在环境工程中也很明显，其中排水系统和管道的设计依赖于管道形成的原理。合理设计的tubulation系统确保了高效的水管理，并减少了城市地区洪水的风险。工程师在创建这些系统时必须考虑流量、材料特性和周围环境等因素。有效的tubulation可以带来可持续的解决方案，最大限度地减少环境影响，同时满足日益增长的人口需求。此外，tubulation不仅限于物理结构；它还可以描述数据传输和网络中的过程。在计算机科学中，数据包通过网络中的“管道”传输的概念可以与tubulation相提并论。理解数据如何高效地通过网络流动对于提高互联网速度和可靠性至关重要。网络工程师致力于优化tubulation协议，确保数据迅速安全地到达目的地。总之，tubulation是一个多面的术语，涵盖了多个领域，突显了管状结构在自然和工程系统中的重要性。无论我们是在讨论生物过程、创新材料、有效的排水系统还是高效的数据传输，tubulation的概念在我们理解和推进这些领域中始终至关重要。随着技术的不断发展，探索tubulation无疑将导致新的发现和应用，从而造福整个社会。