neutral equilibrium

简明释义

中性平衡

英英释义

例句

1.The marble on the table demonstrates neutral equilibrium 中性平衡 as it can easily move without falling off.

桌子上的弹珠展示了中性平衡 neutral equilibrium，因为它可以轻易移动而不会掉落。

2.A flat surface allows a ball to rest in neutral equilibrium 中性平衡, as it can roll in any direction without tipping over.

平坦的表面使得球可以处于中性平衡 neutral equilibrium状态，因为它可以向任何方向滚动而不会翻倒。

3.In physics, neutral equilibrium 中性平衡 occurs when an object's center of mass is at the same height regardless of its position.

在物理学中，当物体的质心无论其位置如何都处于相同高度时，就会出现中性平衡 neutral equilibrium。

4.In design, achieving neutral equilibrium 中性平衡 is crucial for stability in structures like bridges.

在设计中，实现中性平衡 neutral equilibrium对桥梁等结构的稳定性至关重要。

5.In a perfectly balanced system, the object is in neutral equilibrium 中性平衡, meaning it will remain at rest unless acted upon by an external force.

在一个完全平衡的系统中，物体处于中性平衡 neutral equilibrium状态，这意味着它将保持静止，除非受到外力作用。

作文

In the realm of physics and engineering, the concept of neutral equilibrium plays a crucial role in understanding stability. When we think about balance and stability, we often refer to objects that are either in stable or unstable equilibrium. However, neutral equilibrium represents a unique state where an object remains in its position even when subjected to slight disturbances. This characteristic makes neutral equilibrium particularly interesting and relevant in various applications, from architecture to robotics.To illustrate this concept, consider a ball placed on a flat surface. If the ball is nudged slightly, it will not roll back to its original position nor roll away; instead, it will simply stay in the new position. This scenario exemplifies neutral equilibrium, as the forces acting upon the ball are balanced, allowing it to remain in any position it occupies. In contrast, if the ball were placed in a bowl, it would be in stable equilibrium, as any disturbance would cause it to return to the lowest point of the bowl. Conversely, if the ball were placed on top of a dome, it would be in unstable equilibrium, rolling away with any slight push.The implications of neutral equilibrium extend beyond simple physics experiments. In engineering, structures must be designed to withstand various forces while maintaining stability. For instance, a bridge must be able to support its own weight and the weight of vehicles without collapsing. Understanding the principles of neutral equilibrium allows engineers to create designs that can distribute forces evenly, ensuring that no part of the structure is overly stressed.Robotics also benefits from the understanding of neutral equilibrium. When designing robots, engineers must consider how these machines will interact with their environment. A robot that can maintain neutral equilibrium can adapt to changes in its surroundings without falling over. For example, a bipedal robot that can adjust its center of mass will be able to walk on uneven terrain by shifting its weight without losing balance.Moreover, the concept of neutral equilibrium can be applied to various fields, including economics and ecology. In economics, markets can reach a state of neutral equilibrium where supply equals demand. Any slight change in price will not lead to a surplus or shortage, illustrating a balance that can be beneficial for both consumers and producers. Similarly, in ecology, ecosystems can achieve neutral equilibrium when species populations stabilize, allowing for a balanced interaction among different organisms.In conclusion, neutral equilibrium is a fundamental concept that transcends multiple disciplines. Its ability to describe a state of balance in various systems highlights the importance of stability in design and functionality. Whether in physics, engineering, robotics, economics, or ecology, recognizing and applying the principles of neutral equilibrium can lead to more effective solutions and innovations. As we continue to explore and understand the intricacies of this concept, we can better appreciate the delicate balance that exists in our world and strive to create systems that maintain this equilibrium for the benefit of all.

在物理和工程领域，中性平衡的概念在理解稳定性方面起着至关重要的作用。当我们想到平衡和稳定时，我们通常会提到处于稳定或不稳定平衡的物体。然而，中性平衡代表了一种独特的状态，在这种状态下，即使受到轻微干扰，物体也能保持其位置。这一特性使得中性平衡在建筑和机器人等各种应用中尤为有趣和相关。为了说明这一概念，考虑一个放置在平坦表面的球。如果球被轻轻推一下，它不会滚回原来的位置，也不会滚走；相反，它将停留在新的位置。这个场景展示了中性平衡，因为作用在球上的力是平衡的，使它能够保持在任何占据的位置。相比之下，如果球被放置在碗里，它将处于稳定平衡，因为任何干扰都会使其返回碗的最低点。相反，如果球被放置在圆顶顶部，它将处于不稳定平衡，任何轻微的推动都会使其滚走。中性平衡的影响超越了简单的物理实验。在工程中，结构必须设计成能够承受各种力量，同时保持稳定。例如，一座桥必须能够支撑自身重量和车辆重量而不倒塌。理解中性平衡的原理使工程师能够创建可以均匀分配力量的设计，确保结构的任何部分都不会过度受压。机器人技术也受益于对中性平衡的理解。在设计机器人时，工程师必须考虑这些机器将如何与环境互动。能够保持中性平衡的机器人可以适应周围环境的变化，而不会摔倒。例如，能够调整重心的双足机器人能够通过移动重量在不失去平衡的情况下在不平坦的地形上行走。此外，中性平衡的概念可以应用于多个领域，包括经济学和生态学。在经济学中，市场可以达到一种中性平衡状态，其中供给等于需求。价格的任何轻微变化都不会导致过剩或短缺，体现出一种对消费者和生产者都有利的平衡。同样，在生态学中，当物种种群稳定时，生态系统可以实现中性平衡，从而允许不同生物之间的平衡互动。总之，中性平衡是一个基本概念，超越了多个学科。它描述了各种系统中平衡状态的能力突显了设计和功能中稳定性的重要性。无论是在物理、工程、机器人、经济学还是生态学中，认识并应用中性平衡的原则都可以导致更有效的解决方案和创新。随着我们继续探索和理解这一概念的复杂性，我们可以更好地欣赏我们世界中存在的微妙平衡，并努力创建维持这种平衡的系统，以造福所有人。