transmission of energy

简明释义

能量传递

英英释义

例句

1.In power plants, the transmission of energy is crucial for delivering electricity to homes and businesses.

在发电厂，能量传输对将电力输送到家庭和企业至关重要。

2.The efficiency of the solar panels relies heavily on the transmission of energy from sunlight to electricity.

太阳能电池板的效率在很大程度上依赖于阳光到电能的能量传输。

3.In thermodynamics, the transmission of energy between systems is a key concept.

在热力学中，系统之间的能量传输是一个关键概念。

4.The transmission of energy through cables can result in energy loss if not properly insulated.

如果没有适当绝缘，电缆中的能量传输可能会导致能量损失。

5.Engineers study the transmission of energy in order to improve the performance of electric vehicles.

工程师研究能量传输以提高电动车的性能。

作文

The concept of transmission of energy is fundamental to understanding how energy flows in various systems, both natural and artificial. Energy exists in many forms, including thermal, kinetic, potential, and electrical energy. The transmission of energy refers to the process by which energy moves from one location or system to another, often through different mediums. This phenomenon can be observed in countless applications, from the simple act of heating a room to the complex operations of power plants that supply electricity to entire cities.In the context of thermal energy, for example, the transmission of energy occurs when heat moves from a hotter object to a cooler one. This is evident when you place a cold spoon into a hot bowl of soup; the heat transfers from the soup to the spoon until they reach thermal equilibrium. This principle is governed by the laws of thermodynamics and is crucial in designing efficient heating systems in homes and industries.Another significant aspect of the transmission of energy is found in the field of mechanics. When a car accelerates, the engine converts fuel into kinetic energy, which is then transmitted through the drivetrain to the wheels. This transmission of energy allows the vehicle to move forward, demonstrating how energy conversion and transmission work hand in hand in mechanical systems. Understanding this process helps engineers design better vehicles that are more efficient and environmentally friendly.In modern society, the transmission of energy has taken on new dimensions with the advent of electrical energy. Power plants generate electricity using various sources such as fossil fuels, nuclear energy, or renewable resources like wind and solar power. Once generated, this electrical energy must be transmitted over long distances to reach consumers. This is accomplished through an intricate network of power lines and substations, which efficiently carry electricity to homes and businesses. The efficiency of this transmission of energy is critical, as energy losses during transmission can lead to increased costs and environmental impact.Moreover, the transmission of energy is not limited to physical systems; it also plays a vital role in biological processes. For instance, in photosynthesis, plants convert sunlight into chemical energy, which is then transmitted through the food chain as animals consume plants and other animals. This biological transmission of energy is essential for sustaining life on Earth and highlights the interconnectedness of different systems within our ecosystem.As we advance technologically, the need for efficient transmission of energy becomes increasingly important. Innovations in energy storage, such as batteries and supercapacitors, aim to improve the efficiency of energy transmission by storing excess energy generated during peak production times for use during high demand periods. Additionally, smart grid technology is being developed to optimize the distribution and transmission of energy, making energy use more sustainable and reliable.In conclusion, the transmission of energy is a multifaceted concept that permeates every aspect of our lives. From the simple transfer of heat to the complex systems that power our cities, understanding this process is crucial for developing technologies that enhance our quality of life while minimizing environmental impacts. As we continue to innovate and explore new ways to harness and transmit energy, we must remain mindful of the principles that govern these processes to ensure a sustainable future for generations to come.

“能量传输”这一概念是理解能量在各种自然和人工系统中流动的基础。能量存在多种形式，包括热能、动能、势能和电能。“能量传输”指的是能量从一个地点或系统移动到另一个地点或系统的过程，通常通过不同的介质。这一现象可以在无数应用中观察到，从简单的加热房间到为整个城市供电的发电厂的复杂操作。以热能为例，“能量传输”发生在热物体与冷物体之间。当你将一把冷勺子放入热汤中时，热量从汤传递到勺子，直到它们达到热平衡。这一原理受热力学定律的支配，在设计高效的家庭和工业供暖系统时至关重要。“能量传输”的另一个重要方面在于机械领域。当汽车加速时，发动机将燃料转化为动能，然后通过传动系统传递到车轮。这种“能量传输”使车辆向前移动，展示了能量转换与传输在机械系统中的相辅相成。理解这一过程有助于工程师设计出更高效、对环境友好的车辆。在现代社会中，“能量传输”随着电能的出现而呈现出新的维度。发电厂利用各种能源（如化石燃料、核能或可再生资源如风能和太阳能）来发电。一旦产生，这些电能必须通过复杂的电力线路和变电站网络，长距离传输到消费者手中。这种“能量传输”的效率至关重要，因为传输过程中的能量损失会导致成本增加和环境影响。此外，“能量传输”不仅限于物理系统，它在生物过程中的作用也至关重要。例如，在光合作用中，植物将阳光转化为化学能，然后通过食物链传递，动物通过食用植物和其他动物获取能量。这种生物“能量传输”对于维持地球上的生命至关重要，并突显了我们生态系统中不同系统之间的相互联系。随着技术的进步，高效的“能量传输”变得越来越重要。电池和超级电容器等能源存储创新旨在通过在高峰生产时期存储多余能量，以提高能量传输的效率，以便在高需求时期使用。此外，智能电网技术正在开发中，以优化能量的分配和“能量传输”，使能量使用更加可持续和可靠。总之，“能量传输”是一个多方面的概念，渗透到我们生活的方方面面。从简单的热量转移到为城市供电的复杂系统，理解这一过程对于开发提升生活质量的技术，同时减少环境影响至关重要。随着我们不断创新和探索利用和传输能量的新方法，我们必须始终牢记支配这些过程的原则，以确保为后代创造一个可持续的未来。