trunnion seat

简明释义

耳轴座

英英释义

例句

1.During the assembly, we had to tighten the bolts on the trunnion seat for stability.

在组装过程中，我们必须拧紧支座上的螺栓以确保稳定性。

2.The hydraulic system relies on the integrity of the trunnion seat for effective operation.

液压系统依赖于支座的完整性以实现有效操作。

3.We need to replace the trunnion seat before the next maintenance cycle.

我们需要在下一个维护周期之前更换支座。

4.A worn-out trunnion seat can lead to operational failures in machinery.

磨损的支座可能导致机械故障。

5.The engineer inspected the trunnion seat to ensure it was properly aligned.

工程师检查了支座以确保它的对齐正确。

作文

In the world of engineering and mechanics, precision and stability are paramount. One of the critical components that contribute to these qualities in machinery is the trunnion seat. A trunnion seat is a type of support structure that allows an object, such as a cylinder or a shaft, to pivot or rotate around a fixed point. This component is commonly found in various applications, including cranes, military artillery, and large machinery, where controlled movement is essential. The design of a trunnion seat typically involves a cylindrical shape that provides a stable base for the rotating element. The trunnion itself is a protruding part of the main body that fits into the trunnion seat, allowing for smooth rotation. This mechanism is crucial for ensuring that the equipment operates efficiently and safely. For instance, in a crane, the trunnion seat supports the boom, enabling it to swing and lift loads with precision. Understanding the function of a trunnion seat is essential for engineers and designers. They must consider factors such as load capacity, material strength, and the environmental conditions in which the equipment will operate. A well-designed trunnion seat can withstand significant forces while minimizing wear and tear over time. This durability is vital in high-stress environments, where equipment failure could lead to catastrophic accidents. Moreover, the manufacturing process of a trunnion seat is also noteworthy. Engineers often use advanced materials like steel or reinforced composites to ensure strength and longevity. The precision machining involved in creating a trunnion seat is critical; any imperfections can lead to misalignment and operational inefficiencies. In essence, the quality of a trunnion seat directly impacts the overall performance of the machinery it supports. The application of trunnion seats extends beyond traditional machinery. In modern technology, robotic arms and automated systems employ this mechanism to achieve complex movements. For example, in robotics, a trunnion seat allows for a greater range of motion, enabling robots to perform intricate tasks with high accuracy. As industries continue to evolve, the importance of such components will only grow, making it imperative for future engineers to master their design and implementation. In conclusion, the trunnion seat is a fundamental component in many mechanical systems, providing stability and enabling movement. Its design and functionality play a crucial role in the efficiency and safety of various applications. As technology advances, the relevance of the trunnion seat remains steadfast, highlighting the need for ongoing research and innovation in this area. Understanding the intricacies of a trunnion seat not only benefits engineers but also enhances the reliability of the machinery that society depends on every day.

在工程和机械的世界中，精确性和稳定性至关重要。支撑这些特性的关键组件之一是支座。支座是一种支撑结构，允许物体（如圆柱或轴）围绕固定点进行旋转或转动。这个组件通常在各种应用中找到，包括起重机、军用炮兵和大型机械，在这些应用中，受控运动是必不可少的。支座的设计通常涉及一种圆柱形状，为旋转元件提供稳定的基础。支座本身是主机身的一个突起部分，适合进入支座中，从而实现平稳旋转。这个机制对于确保设备高效、安全地运行至关重要。例如，在起重机中，支座支撑着吊臂，使其能够精确地摆动和提升负载。理解支座的功能对工程师和设计师至关重要。他们必须考虑负载能力、材料强度以及设备将要运行的环境条件。设计良好的支座可以承受显著的力，同时最大限度地减少磨损。这种耐用性在高应力环境中至关重要，因为设备故障可能导致灾难性事故。此外，支座的制造过程也值得注意。工程师通常使用钢材或增强复合材料等先进材料，以确保强度和耐用性。制造支座所需的精密加工至关重要；任何不完美都可能导致对准不当和操作效率低下。本质上，支座的质量直接影响其所支持的机械的整体性能。支座的应用超越了传统机械。在现代技术中，机器人手臂和自动化系统采用这种机制来实现复杂的运动。例如，在机器人技术中，支座允许更大的运动范围，使机器人能够以高精度执行复杂任务。随着行业的不断发展，这种组件的重要性只会增加，因此未来的工程师掌握其设计和实施变得至关重要。总之，支座是许多机械系统中的基本组件，提供稳定性并使运动成为可能。其设计和功能在各种应用的效率和安全性中发挥着至关重要的作用。随着技术的进步，支座的相关性依然坚定，突显了在这一领域持续研究和创新的必要性。理解支座的复杂性不仅有利于工程师，也增强了社会日常依赖的机械的可靠性。