thermal steering

简明释义

热引导

英英释义

例句

1.The researchers are exploring thermal steering 热量引导 as a method to enhance solar panel efficiency.

研究人员正在探索热量引导作为提高太阳能电池板效率的一种方法。

2.By utilizing thermal steering 热量引导, the team was able to reduce energy consumption in their manufacturing process.

通过利用热量引导，团队能够减少制造过程中的能耗。

3.The engineers implemented thermal steering 热量引导 techniques to optimize the cooling system of the new data center.

工程师们实施了热量引导技术，以优化新数据中心的冷却系统。

4.The concept of thermal steering 热量引导 is crucial in designing more efficient electronic devices.

在设计更高效的电子设备时，热量引导的概念至关重要。

5.In aerospace engineering, thermal steering 热量引导 helps manage heat distribution across the aircraft.

在航空航天工程中，热量引导有助于管理飞机的热分布。

作文

In recent years, the concept of thermal steering has gained significant attention in various fields, particularly in engineering and environmental science. Thermal steering refers to the ability to control or manipulate thermal energy to achieve desired outcomes, such as enhancing energy efficiency, improving system performance, or mitigating heat-related issues. This innovative approach can be observed in several applications, including building design, electronic devices, and even climate control systems. One of the most prominent areas where thermal steering is applied is in architectural design. Modern buildings are increasingly designed with an emphasis on sustainability and energy efficiency. By utilizing thermal steering techniques, architects can optimize the thermal properties of a building. For instance, strategically placed windows can allow for natural light while minimizing heat gain during the summer months. Additionally, advanced materials that reflect or absorb heat can be incorporated into the building’s façade to regulate indoor temperatures effectively. This not only reduces the reliance on artificial heating and cooling systems but also contributes to lower energy bills and a smaller carbon footprint.Another critical application of thermal steering is in the realm of electronics. As technology advances, electronic devices become more powerful, which often leads to increased heat generation. If not managed properly, this excess heat can cause malfunctions or reduce the lifespan of components. Engineers are now employing thermal steering strategies to manage heat dissipation in devices such as smartphones, computers, and servers. By using heat sinks, thermal interface materials, and innovative cooling methods, they can effectively direct heat away from sensitive components, ensuring optimal performance and longevity.Moreover, thermal steering plays a vital role in climate control systems. In HVAC (Heating, Ventilation, and Air Conditioning) systems, the efficient distribution of thermal energy is crucial for maintaining comfortable indoor environments. With advancements in smart technology, it is now possible to implement thermal steering through the use of sensors and automated controls. These systems can detect temperature variations and adjust heating or cooling outputs accordingly, resulting in enhanced comfort and energy savings.The significance of thermal steering extends beyond individual buildings or devices; it has broader implications for urban planning and climate resilience. As cities grow and face challenges related to urban heat islands and climate change, the principles of thermal steering can inform strategies for creating more livable environments. For example, incorporating green roofs, reflective pavements, and strategically placed vegetation can help manage heat within urban landscapes, contributing to cooler temperatures and improved air quality.In conclusion, thermal steering is a multifaceted concept that encompasses various applications aimed at managing thermal energy effectively. From architecture to electronics and climate control, the ability to steer thermal energy plays a crucial role in enhancing efficiency, performance, and sustainability. As we continue to confront global challenges related to energy consumption and climate change, embracing thermal steering will be essential in shaping a more sustainable future. By integrating these principles into our designs and technologies, we can pave the way for innovations that not only meet our current needs but also preserve our environment for generations to come.

近年来，热引导的概念在各个领域，特别是在工程和环境科学中，受到了广泛关注。热引导是指控制或操纵热能以实现所需结果的能力，例如提高能效、改善系统性能或缓解与热相关的问题。这种创新方法可以在多种应用中观察到，包括建筑设计、电子设备甚至气候控制系统。热引导应用最显著的领域之一是建筑设计。现代建筑越来越重视可持续性和能效。通过利用热引导技术，建筑师可以优化建筑的热属性。例如，战略性地放置窗户可以在夏季减少热量增加的同时允许自然光进入。此外，可以将反射或吸收热量的先进材料纳入建筑外立面，以有效调节室内温度。这不仅减少了对人工加热和冷却系统的依赖，还降低了能源账单并减少了碳足迹。热引导的另一个关键应用是在电子领域。随着技术的进步，电子设备变得越来越强大，这往往导致热量增加。如果不加以管理，这些多余的热量可能会导致故障或缩短组件的使用寿命。工程师现在正在采用热引导策略来管理智能手机、计算机和服务器等设备中的热散发。通过使用散热器、热界面材料和创新冷却方法，他们可以有效地将热量从敏感组件中引导出去，确保最佳性能和使用寿命。此外，热引导在气候控制系统中也发挥着至关重要的作用。在HVAC（供暖、通风和空调）系统中，热能的有效分配对于维持舒适的室内环境至关重要。随着智能技术的进步，现在可以通过传感器和自动控制来实施热引导。这些系统可以检测温度变化并相应调整加热或冷却输出，从而提高舒适度和节能效果。热引导的重要性超越了单个建筑或设备；它对城市规划和气候韧性具有更广泛的影响。随着城市的发展以及面临城市热岛和气候变化带来的挑战，热引导的原则可以为创造更宜居环境提供信息。例如，结合绿色屋顶、反射性路面和战略性种植植被可以帮助管理城市景观中的热量，有助于降低温度和改善空气质量。总之，热引导是一个多方面的概念，涵盖了旨在有效管理热能的各种应用。从建筑到电子产品和气候控制，操控热能的能力在提高效率、性能和可持续性方面发挥着至关重要的作用。随着我们继续面对与能源消耗和气候变化相关的全球挑战，接受热引导将对塑造更可持续的未来至关重要。通过将这些原则融入我们的设计和技术中，我们可以为创新铺平道路，这些创新不仅满足我们当前的需求，还能为子孙后代保护我们的环境。