expansion trunk hatchway

简明释义

膨胀舱口

英英释义

例句

1.The car's expansion trunk hatchway allows for easy access to larger items without removing the back seats.

这款车的扩展行李厢舱口允许更方便地取用较大的物品，而无需拆卸后座。

2.During the road trip, we utilized the expansion trunk hatchway to store our camping gear.

在公路旅行中，我们利用扩展行李厢舱口存放我们的露营装备。

3.The engineer designed a new model with an expansion trunk hatchway to improve cargo capacity.

工程师设计了一种新模型，配备了一个扩展行李厢舱口以提高货物容量。

4.When shopping for a new SUV, I made sure it had an expansion trunk hatchway for added convenience.

在购买新SUV时，我确保它有一个扩展行李厢舱口以增加便利性。

5.We were impressed by the expansion trunk hatchway feature in the latest model, which enhances storage options.

我们对最新型号中的扩展行李厢舱口功能印象深刻，这增强了储物选项。

作文

In the world of engineering and architecture, the term expansion trunk hatchway refers to a specific design feature that allows for the expansion and contraction of materials due to temperature changes. This concept is crucial in various applications, particularly in construction and manufacturing processes where materials are subjected to thermal stress. Understanding how to implement an expansion trunk hatchway can significantly enhance the durability and functionality of structures. The basic idea behind an expansion trunk hatchway is to provide a designated space or opening that accommodates the natural movement of materials. For instance, metals expand when heated and contract when cooled. If a metal structure does not allow for this movement, it can lead to warping, cracking, or even catastrophic failure. Therefore, engineers incorporate expansion trunk hatchways into their designs to mitigate these risks. One common application of expansion trunk hatchways is in bridges. Bridges experience significant temperature fluctuations, which can cause the materials to expand and contract. By including expansion trunk hatchways, engineers can ensure that the bridge remains stable and safe for use. These hatchways act as flexible points that absorb the stresses caused by thermal changes, allowing the bridge to maintain its integrity over time.Moreover, expansion trunk hatchways are not limited to large structures like bridges; they can also be found in smaller applications, such as piping systems. In industrial settings, pipes often carry fluids at varying temperatures. If the pipes are rigidly fixed, the thermal expansion of the fluid can create dangerous pressure build-ups. Incorporating expansion trunk hatchways in these systems allows for safe expansion without risking damage to the pipes or the surrounding infrastructure.Furthermore, the design of an expansion trunk hatchway must consider several factors, including the type of material used, the expected temperature range, and the specific application. Engineers must calculate the amount of expansion that might occur and design the hatchway accordingly. This requires a deep understanding of material science and thermodynamics, making the role of the engineer vital in ensuring safety and efficiency.In conclusion, the expansion trunk hatchway is an essential component in modern engineering that addresses the challenges posed by thermal expansion. Its proper implementation not only enhances the longevity of structures but also ensures the safety of those who use them. As our world continues to evolve and face new engineering challenges, the importance of understanding concepts like the expansion trunk hatchway will only grow. Therefore, it is imperative for future engineers and architects to grasp these concepts thoroughly, ensuring that they can design safe and effective structures that withstand the test of time.

在工程和建筑的世界中，术语膨胀箱舱口指的是一种特定的设计特征，允许材料因温度变化而膨胀和收缩。这个概念在建筑和制造过程中至关重要，因为材料会受到热应力的影响。理解如何实现膨胀箱舱口可以显著增强结构的耐久性和功能性。膨胀箱舱口的基本思想是提供一个指定的空间或开口，以适应材料的自然运动。例如，金属在加热时会膨胀，而在冷却时会收缩。如果金属结构不允许这种运动，可能会导致翘曲、开裂甚至灾难性的失败。因此，工程师在设计中加入膨胀箱舱口以减轻这些风险。膨胀箱舱口的一个常见应用是在桥梁上。桥梁经历显著的温度波动，这可能导致材料膨胀和收缩。通过包括膨胀箱舱口，工程师可以确保桥梁保持稳定和安全。这些舱口作为灵活的点，吸收由热变化引起的应力，从而使桥梁随着时间的推移保持其完整性。此外，膨胀箱舱口不仅限于像桥梁这样的大型结构；它们也可以在较小的应用中找到，例如管道系统。在工业环境中，管道通常运输不同温度的流体。如果管道被刚性固定，流体的热膨胀可能会造成危险的压力积聚。在这些系统中加入膨胀箱舱口可以安全地容许膨胀，而不会对管道或周围基础设施造成损害。此外，膨胀箱舱口的设计必须考虑多个因素，包括所用材料的类型、预期的温度范围以及具体的应用。工程师必须计算可能发生的膨胀量，并相应地设计舱口。这需要对材料科学和热力学有深入的理解，使工程师在确保安全和效率方面的角色至关重要。总之，膨胀箱舱口是现代工程中的一个重要组成部分，它解决了热膨胀带来的挑战。其正确实施不仅增强了结构的耐久性，还确保了使用者的安全。随着我们世界的不断发展和面临新的工程挑战，理解像膨胀箱舱口这样的概念的重要性只会增加。因此，未来的工程师和建筑师必须彻底掌握这些概念，确保他们能够设计出经得起时间考验的安全有效的结构。