clock mechanism

简明释义

定时机构

英英释义

例句

1.Understanding the clock mechanism 钟表机制 is essential for any horologist.

理解钟表机制 钟表机制对任何制表师来说都是必不可少的。

2.After studying the clock mechanism 钟表机制, she decided to pursue a career in watchmaking.

在研究了钟表机制 钟表机制后，她决定追求制表的职业。

3.The clock mechanism 钟表机制 in this wall clock is powered by a battery.

这款挂钟的钟表机制 钟表机制由电池供电。

4.The intricate design of the clock mechanism 钟表机制 allows for precise timekeeping.

复杂的钟表机制 钟表机制设计使得时间保持非常精准。

5.He opened the antique clock to repair the clock mechanism 钟表机制 inside.

他打开了古董钟以修理里面的钟表机制 钟表机制。

作文

The concept of a clock mechanism is fascinating and intricate, serving as the heart of timekeeping devices. A clock mechanism refers to the internal components that work together to measure and display time accurately. These mechanisms have evolved significantly over the centuries, transitioning from simple sundials to complex quartz and atomic clocks. Understanding the clock mechanism involves delving into the various parts that contribute to its functionality, including gears, springs, and pendulums.Historically, the earliest timekeeping devices relied on natural phenomena, such as the position of the sun. However, as society progressed, the need for more precise time measurement arose, leading to the development of mechanical clocks. The clock mechanism in these early devices was primarily driven by a weight or spring that would release energy gradually, allowing the gears to turn at a consistent rate. This innovation marked a significant advancement in horology, the study of timekeeping.One of the most crucial components of a clock mechanism is the escapement, which regulates the release of energy from the power source. The escapement allows the gear train to advance in controlled increments, ensuring that the clock ticks at the correct intervals. This precision is vital for maintaining accurate time, and any malfunction in the escapement can result in a clock that runs too fast or too slow.In modern times, quartz technology has revolutionized the clock mechanism. Quartz clocks utilize a small crystal that vibrates at a specific frequency when an electric current passes through it. This vibration is then converted into a precise timekeeping signal, making quartz clocks incredibly accurate compared to their mechanical counterparts. The simplicity and reliability of the quartz clock mechanism have made it the standard for most consumer clocks today.Moreover, the advent of atomic clocks has taken timekeeping to an entirely new level. An atomic clock mechanism operates based on the vibrations of atoms, typically cesium or rubidium. These clocks are so precise that they can measure time to within billionths of a second. The implications of such accuracy are profound, impacting everything from global positioning systems (GPS) to telecommunications, where synchronization is critical.Despite the advancements in technology, traditional mechanical clocks with intricate clock mechanisms still hold a special place in society. Many people appreciate the craftsmanship involved in creating these timepieces, often viewing them as works of art rather than mere instruments for telling time. Collectors and enthusiasts often seek out vintage clocks, admiring the complexity of their clock mechanisms and the history behind each piece.In conclusion, the clock mechanism is a testament to human ingenuity and the relentless pursuit of precision. From ancient sundials to sophisticated atomic clocks, the evolution of timekeeping reflects our desire to understand and measure the passage of time accurately. Whether one prefers the charm of a mechanical clock or the precision of a quartz or atomic model, the clock mechanism remains an essential aspect of our daily lives, reminding us of the importance of time in our fast-paced world.

“钟表机芯”的概念既迷人又复杂，是计时设备的核心。“钟表机芯”指的是内部组件，它们共同工作以准确测量和显示时间。这些机制在几个世纪中经历了显著的演变，从简单的日晷过渡到复杂的石英钟和原子钟。理解“钟表机芯”需要深入了解构成其功能的各种部分，包括齿轮、弹簧和摆锤。从历史上看，最早的计时设备依赖于自然现象，如太阳的位置。然而，随着社会的进步，对更精确时间测量的需求出现，导致机械钟的发展。这些早期设备中的“钟表机芯”主要由一个重物或弹簧驱动，逐渐释放能量，使齿轮以一致的速度转动。这一创新标志着制表学的重大进步，即研究计时的学科。“钟表机芯”中最重要的组成部分之一是擒纵器，它调节能量从动力源的释放。擒纵器允许齿轮传动系统以受控增量前进，确保时钟以正确的间隔滴答作响。这种精确性对保持准确的时间至关重要，擒纵器的任何故障都可能导致时钟运行过快或过慢。在现代，石英技术彻底改变了“钟表机芯”。石英钟利用一个小晶体，当电流通过时，它会以特定频率振动。这种振动随后被转换为精确的计时信号，使石英钟与其机械同类相比极其准确。石英“钟表机芯”的简单性和可靠性使其成为今天大多数消费时钟的标准。此外，原子钟的出现将计时提升到了一个全新的水平。原子“钟表机芯”基于原子的振动，通常是铯或铷。这些时钟的精确度如此之高，以至于它们可以测量到十亿分之一秒的时间。这种准确性的影响深远，影响着从全球定位系统（GPS）到电信等各个领域，在这些领域中，时间同步至关重要。尽管技术进步，传统机械钟及其复杂的“钟表机芯”在社会中仍然占有特殊地位。许多人欣赏制作这些时计所涉及的工艺，往往将其视为艺术品，而不仅仅是告诉时间的工具。收藏家和爱好者常常寻找复古时钟，欣赏其“钟表机芯”的复杂性以及每件作品背后的历史。总之，“钟表机芯”是人类智慧和对精确追求的证明。从古代日晷到复杂的原子钟，计时的发展反映了我们准确理解和测量时间流逝的愿望。无论人们更喜欢机械钟的魅力，还是石英或原子模型的精确性，“钟表机芯”依然是我们日常生活中不可或缺的一部分，提醒我们在快节奏的世界中时间的重要性。