weber
简明释义
n. 韦伯(磁通单位)
n. (Weber)人名;(英、法、德、葡、罗、匈、捷、芬、瑞典)韦伯
英英释义
A unit of measurement for magnetic flux in the International System of Units (SI), equal to one volt-second per ampere. | 国际单位制(SI)中用于测量磁通量的单位,等于一个伏特秒每安培。 |
单词用法
马克斯·韦伯(德国学者) | |
韦伯数 |
同义词
反义词
| 安培 | The current flowing through the circuit is measured in amperes. | 电路中流动的电流以安培为单位测量。 | |
| 伏特 | 电阻器两端的电压是5伏特。 |
例句
1.But Mr Weber and the similarly orthodox Mr Warsh have departed.
但是韦伯以及同样信奉正统政策的沃什都已经离开了。
2.But even back then, Weber says, people generally preferred praising thrift to actually practicing it.
但是即使回到当时,韦伯说,人们通常喜欢赞扬节俭更胜于实际实行。
3.Weber commented that many breathtakingly beautiful, natural places are still unknown to many of us.
韦伯评论道,我们中的许多人对于诸多具有惊人之美的自然景观还一无所知。
4.The publications are similar to "A&F Quarterly", a racy magalog also produced by Weber.
这些出版物类似于韦伯出版的《A&F季刊》,这是一本生动活泼的杂志。
5.Garret Weber-Gale and Michael Phelps display an evolutionary trait.
盖尔和菲尔普斯展示出了进化和特点。
6.The 1, 400-seat Browning Center auditorium at Weber State University was sold out. The crowd loved her.
独奏会地点在韦伯州立大学的布朗宁中心大礼堂,共有1400个座位,当天座无虚席。
7.Axel Weber said on Friday that he'll step down as President of the German Bundesbank.
AxelWeber说本周五他将辞去德国联邦银行总裁职务。
8.To calculate the total magnetic flux, you need to multiply the area by the magnetic field strength in weber.
要计算总磁通量,需要将面积与磁场强度相乘,结果以韦伯为单位。
9.One weber is equal to one volt-second.
一个韦伯等于一个伏特秒。
10.In electromagnetic theory, weber plays a crucial role in defining the behavior of circuits.
在电磁理论中,韦伯在定义电路行为方面起着至关重要的作用。
11.The unit of magnetic flux density is tesla, which is derived from weber.
磁通密度的单位是特斯拉,它是从韦伯推导而来的。
12.The magnetic flux through the circuit is measured in weber.
电路中的磁通量以韦伯为单位测量。
作文
The concept of a weber is fundamental in the field of electromagnetism and physics. Named after the German physicist Wilhelm Eduard Weber, the weber is the SI unit of magnetic flux. Understanding this unit is crucial for anyone studying electrical engineering or physics because it helps quantify the amount of magnetic field passing through a given area. In simple terms, one weber is defined as the amount of magnetic flux that, when linked with a circuit, induces an electromotive force of one volt as the magnetic field changes at a rate of one weber per second. This definition connects the weber to Faraday's law of electromagnetic induction, which describes how a change in magnetic field can generate electricity.To truly grasp the significance of the weber, one must explore its applications in real-world scenarios. For instance, in electric generators, the magnetic flux represented in webers is essential for understanding how electricity is produced. The more webers that pass through the coils of wire in a generator, the greater the potential for generating electrical energy. This relationship highlights the importance of magnetic fields in our daily lives, from powering our homes to enabling the functioning of various electronic devices.Moreover, the weber is not just a theoretical concept; it has practical implications in designing electrical systems. Engineers must consider the magnetic flux in their designs to ensure that devices operate efficiently and safely. For example, transformers, which are used to increase or decrease voltage levels in power lines, rely heavily on the principles of magnetic flux measured in webers. A transformer’s efficiency is directly related to the amount of magnetic flux it can effectively manage, making the understanding of webers critical for engineers in the field.In addition to its technical applications, the weber also plays a role in scientific research. Researchers studying magnetic materials often measure properties in webers to determine how different substances react to magnetic fields. This research can lead to advancements in various technologies, including data storage solutions and magnetic resonance imaging (MRI) in medicine. By manipulating and understanding magnetic flux in webers, scientists can innovate new methods and technologies that improve our quality of life.In conclusion, the weber is much more than just a unit of measurement; it represents a fundamental aspect of how we understand and interact with the world around us. From generating electricity to advancing medical technologies, the implications of the weber are vast and significant. As we continue to develop new technologies and deepen our understanding of physics, the weber will undoubtedly remain a crucial element in the ongoing exploration of electromagnetism and its applications. Therefore, mastering the concept of the weber is essential for students and professionals alike in the fields of science and engineering.
“weber”这个概念在电磁学和物理学领域中是基本的。它以德国物理学家威廉·爱德华·韦伯的名字命名,是磁通量的国际单位制(SI)单位。理解这个单位对于任何学习电气工程或物理学的人来说都是至关重要的,因为它有助于量化通过给定面积的磁场量。简单来说,一个weber被定义为当与电路相连的磁通量在以每秒一个weber的速率变化时,诱发一个伏特的电动势。这一定义将weber与法拉第电磁感应定律联系起来,该定律描述了磁场的变化如何产生电力。要真正掌握weber的重要性,人们必须探索其在现实世界中的应用。例如,在发电机中,表示为weber的磁通量对于理解电力的产生至关重要。通过发电机线圈的weber越多,产生电能的潜力就越大。这种关系突显了磁场在我们日常生活中的重要性,从为我们的家供电到使各种电子设备正常运转。此外,weber不仅仅是一个理论概念;它在设计电气系统中具有实际意义。工程师必须在设计中考虑磁通量,以确保设备高效且安全地运行。例如,变压器用于在电力线上升高或降低电压水平,严重依赖于以weber为单位衡量的磁通量的原理。变压器的效率直接与它能够有效管理的磁通量的数量有关,这使得对工程师而言,理解weber至关重要。除了技术应用外,weber还在科学研究中发挥作用。研究磁性材料的研究人员通常以weber为单位测量性质,以确定不同物质如何对磁场反应。这项研究可以推动各种技术的进步,包括数据存储解决方案和医学中的磁共振成像(MRI)。通过操控和理解以weber为单位的磁通量,科学家们可以创新出改善我们生活质量的新方法和技术。总之,weber不仅仅是一个测量单位;它代表了我们理解和与周围世界互动的基本方面。从发电到推动医学技术的进步,weber的影响是广泛而重要的。随着我们继续开发新技术并加深对物理学的理解,weber无疑将继续成为电磁学及其应用的探索中的关键元素。因此,掌握weber的概念对于科学和工程领域的学生和专业人士来说都是至关重要的。
