thermotics
简明释义
n. [热] 热学
英英释义
Thermotics refers to the study and application of thermal processes and energy transfer, particularly in relation to heating and cooling systems. | 热学是指热过程和能量传递的研究与应用,特别是与加热和冷却系统相关的内容。 |
单词用法
热学分析 | |
热学特性 | |
热学工程 | |
热学系统 |
同义词
反义词
| 寒冷 | 冬季空气的寒冷可能非常严酷。 | ||
| 凉爽 | I prefer the coolness of the evening to the heat of the day. | 我更喜欢晚上的凉爽,而不是白天的炎热。 |
例句
1.It is suggested that the monsoon abnormity in plateau is affected by the special surface thermotics which is the media of winter monsoon abnormity leading to summer monsoon abnormity.
高原季风异常可能与高原下垫面热力异常有关,从而推测冬季风异常通过高原这个巨大的热载体而影响夏季风异常。
2.It is suggested that the monsoon abnormity in plateau is affected by the special surface thermotics which is the media of winter monsoon abnormity leading to summer monsoon abnormity.
高原季风异常可能与高原下垫面热力异常有关,从而推测冬季风异常通过高原这个巨大的热载体而影响夏季风异常。
3.The study of thermotics helps in developing better insulation materials.
对热力学的研究有助于开发更好的绝缘材料。
4.Innovative thermotics solutions can significantly reduce heating costs in homes.
创新的热力学解决方案可以显著降低家庭取暖费用。
5.Understanding thermotics is crucial for engineers working on climate control systems.
理解热力学对从事气候控制系统工作的工程师至关重要。
6.Incorporating thermotics into product design can enhance user comfort.
将热力学纳入产品设计可以增强用户舒适度。
7.The new building was designed with advanced thermotics to ensure energy efficiency.
这座新建筑采用了先进的热力学设计,以确保能源效率。
作文
In recent years, the field of science and technology has made significant advancements, particularly in areas related to energy efficiency and environmental sustainability. One such area that has gained attention is thermotics (热动学), which focuses on the study of heat transfer and its applications. Understanding thermotics is essential for developing new technologies that can help mitigate climate change and improve energy consumption in various sectors.The term thermotics encompasses a wide range of concepts, including conduction, convection, and radiation. These three mechanisms describe how heat moves through different materials and environments. For instance, conduction occurs when heat is transferred through direct contact between materials, while convection involves the movement of heat through fluids. Radiation, on the other hand, refers to the transfer of heat in the form of electromagnetic waves. By mastering these principles, engineers and scientists can design more effective thermal systems that optimize energy use.One of the most promising applications of thermotics is in the field of building design. Architects and builders are increasingly incorporating thermotic principles into their projects to create energy-efficient structures. This includes using materials with high thermal mass, which can absorb and store heat, as well as designing buildings that maximize natural ventilation. By doing so, they can reduce the need for artificial heating and cooling systems, ultimately lowering energy costs and minimizing the environmental impact.Moreover, the automotive industry is also benefiting from advancements in thermotics. Modern vehicles are designed with improved thermal management systems that enhance fuel efficiency and reduce emissions. For example, engineers are developing innovative cooling systems that maintain optimal engine temperatures, which not only boosts performance but also prolongs the lifespan of the vehicle. The integration of thermotics in automotive design is a crucial step toward creating greener transportation options.In addition to buildings and vehicles, thermotics plays a vital role in electronics. As devices become smaller and more powerful, managing heat is becoming increasingly important. Overheating can lead to reduced performance and even failure of electronic components. By applying thermotic principles, engineers can design better cooling solutions, such as heat sinks and fans, that effectively dissipate heat and ensure the longevity of electronic devices.Furthermore, the growing interest in renewable energy sources has also highlighted the importance of thermotics. Solar panels, for instance, rely on thermotic principles to convert sunlight into usable energy. Understanding how heat interacts with different materials can lead to the development of more efficient solar technologies, ultimately making renewable energy more accessible and effective.In conclusion, thermotics (热动学) is a critical field that impacts various aspects of our daily lives, from the buildings we inhabit to the vehicles we drive and the electronics we use. As we continue to face challenges related to energy consumption and environmental sustainability, the knowledge and application of thermotics will be essential in driving innovation and creating a more sustainable future. By investing in research and education in this area, we can harness the power of heat transfer to build a better world for generations to come.
近年来,科学和技术领域取得了显著的进步,特别是在与能源效率和环境可持续性相关的领域。其中一个引起关注的领域是热动学(thermotics),它专注于热传递及其应用的研究。理解热动学对于开发能够缓解气候变化并改善各个行业能源消耗的新技术至关重要。热动学这个术语涵盖了广泛的概念,包括导热、对流和辐射。这三种机制描述了热量如何在不同材料和环境中移动。例如,导热发生在材料之间直接接触时,而对流则涉及通过流体移动热量。另一方面,辐射是指以电磁波的形式转移热量。通过掌握这些原理,工程师和科学家可以设计出更有效的热系统,以优化能源使用。热动学最有前景的应用之一是在建筑设计领域。建筑师和施工者越来越多地将热动学原理融入他们的项目中,以创建节能结构。这包括使用具有高热质量的材料,这些材料可以吸收和储存热量,以及设计最大化自然通风的建筑。通过这样做,他们可以减少人工供暖和制冷系统的需求,从而降低能源成本并最小化环境影响。此外,汽车工业也从热动学的进步中受益。现代车辆采用改进的热管理系统,提高燃油效率并减少排放。例如,工程师正在开发创新的冷却系统,以保持发动机的最佳温度,这不仅提高了性能,还延长了车辆的使用寿命。在汽车设计中融入热动学是朝着创造更环保交通选择迈出的关键一步。除了建筑和车辆,热动学在电子产品中也发挥着重要作用。随着设备变得越来越小且功能更强大,管理热量变得越来越重要。过热可能导致电子组件性能下降甚至故障。通过应用热动学原理,工程师可以设计出更好的冷却解决方案,例如散热器和风扇,有效散发热量,确保电子设备的耐用性。此外,日益增长的可再生能源来源的兴趣也突显了热动学的重要性。太阳能电池板例如,依赖于热动学原理将阳光转化为可用能源。理解热量如何与不同材料相互作用可以促进更高效的太阳能技术的发展,最终使可再生能源变得更加可及和有效。总之,热动学(thermotics)是一个关键领域,影响着我们日常生活的各个方面,从我们居住的建筑到我们驾驶的车辆以及我们使用的电子设备。随着我们继续面临与能源消费和环境可持续性相关的挑战,了解和应用热动学将对推动创新和创造一个更可持续的未来至关重要。通过在这一领域投资研究和教育,我们可以利用热传递的力量,为未来几代人建设一个更美好的世界。
