electrothermic

简明释义

英[ɪˈlɛk.trəˌθɜː.mɪk]美[ɪˈlɛk.trəˌθɜr.mɪk]

adj. 电热的，电致热的

英英释义

单词用法

同义词

反义词

例句

1.The study of electrothermic resin is introduced in the paper, this kind of resin is one of the best heating materials for FRP mold.

本文介绍了电热变温树脂的研制。电热变温树脂是玻璃钢模具加热的最佳材料之一。

2.The study of electrothermic resin is introduced in the paper, this kind of resin is one of the best heating materials for FRP mold.

本文介绍了电热变温树脂的研制。电热变温树脂是玻璃钢模具加热的最佳材料之一。

3.The new manufacturing process utilizes electrothermic heating to improve efficiency.

新制造工艺利用电热加热来提高效率。

4.In the lab, we tested the electrothermic properties of various materials.

在实验室，我们测试了各种材料的电热特性。

5.The electrothermic furnace is capable of reaching very high temperatures quickly.

这台电热炉能够迅速达到非常高的温度。

6.Using electrothermic methods can significantly reduce production costs.

使用电热方法可以显著降低生产成本。

7.The electrothermic treatment improved the material's strength.

该电热处理提高了材料的强度。

作文

In recent years, the advancement of technology has led to the development of various innovative methods for heating and processing materials. One such method is known as electrothermic, which refers to the use of electrical energy to generate heat for various applications. This technique has gained popularity in industries such as metallurgy, ceramics, and even food processing due to its efficiency and precision. Understanding the principles behind electrothermic processes can provide insights into their advantages and potential future developments. The basic concept of electrothermic heating involves passing an electric current through a material, which then converts the electrical energy into thermal energy. This process can be achieved through various methods, including resistive heating, induction heating, and microwave heating. Each of these methods has its own set of advantages and limitations, making them suitable for different applications. For instance, resistive heating is commonly used in applications where direct contact with the material is possible. In this method, the material itself acts as a resistor, generating heat as the current flows through it. This approach is often utilized in metal melting and forging processes, where precise temperature control is essential. On the other hand, induction heating is a non-contact method that utilizes electromagnetic fields to heat conductive materials. This technique is particularly advantageous for applications requiring rapid heating and cooling cycles, such as in the treatment of metals. The ability to achieve high temperatures quickly while minimizing energy consumption makes electrothermic induction heating an attractive option for many industries. Microwave heating, another form of electrothermic processing, has gained attention in recent years for its unique ability to heat materials uniformly and selectively. By using microwave radiation, this method can penetrate materials and heat them from within, reducing the risk of thermal gradients that can lead to defects. This characteristic is especially beneficial in the production of ceramics and composites, where uniform heating is critical for achieving desired properties. The environmental impact of electrothermic processes is also worth considering. As industries strive to reduce their carbon footprint, the efficiency of electrical heating methods presents a compelling advantage. Traditional fossil fuel-based heating systems often result in significant greenhouse gas emissions, whereas electrothermic methods can be powered by renewable energy sources, further promoting sustainability. Moreover, the versatility of electrothermic heating techniques allows for their implementation in a wide range of applications. From the production of high-quality steel to the manufacturing of advanced ceramics, the adaptability of these methods can help industries meet the demands of modern consumers for better quality products. In conclusion, the term electrothermic encompasses a variety of heating techniques that utilize electrical energy to produce heat. With applications spanning multiple industries, the efficiency, precision, and environmental benefits of electrothermic processes make them an essential focus for future research and development. As technology continues to evolve, we can expect to see even more innovative applications of electrothermic heating methods, paving the way for a more sustainable and efficient industrial landscape.

近年来，技术的进步导致了各种创新加热和处理材料的方法的发展。其中一种方法被称为电热，指的是利用电能生成热量以用于各种应用。这种技术在冶金、陶瓷甚至食品加工等行业中越来越受欢迎，因为它的效率和精确性。理解电热过程背后的原理可以提供对其优势和潜在未来发展的见解。 电热加热的基本概念涉及通过材料传递电流，从而将电能转化为热能。这一过程可以通过多种方法实现，包括电阻加热、感应加热和微波加热。这些方法各有优缺点，使其适合不同的应用。 例如，电阻加热通常用于可以直接接触材料的应用。在这种方法中，材料本身充当电阻体，随着电流的流动产生热量。这种方法常用于金属熔化和锻造过程中，在这些过程中，精确的温度控制至关重要。 另一方面，感应加热是一种非接触方法，利用电磁场加热导电材料。这项技术特别适用于需要快速加热和冷却周期的应用，例如金属处理。能够快速达到高温，同时最小化能耗，使得电热感应加热成为许多行业的一个有吸引力的选择。 微波加热是另一种电热处理形式，近年来因其独特的均匀和选择性加热材料的能力而受到关注。通过使用微波辐射，这种方法可以穿透材料并从内部加热它们，减少因热梯度导致缺陷的风险。这一特性在陶瓷和复合材料的生产中尤其有利，因为均匀加热对于实现所需的特性至关重要。 电热过程的环境影响也值得考虑。随着各行业努力减少碳足迹，电加热方法的效率呈现出令人信服的优势。传统的基于化石燃料的加热系统往往导致显著的温室气体排放，而电热方法可以由可再生能源驱动，进一步促进可持续性。 此外，电热加热技术的多功能性使其能够在广泛的应用中实施。从高质量钢铁的生产到先进陶瓷的制造，这些方法的适应性可以帮助行业满足现代消费者对更好质量产品的需求。 总之，术语电热涵盖了多种利用电能产生热量的加热技术。随着应用范围跨越多个行业，电热过程的效率、精确性和环境效益使其成为未来研究和发展的重要焦点。随着技术的不断发展，我们可以期待看到更多创新的电热加热方法的应用，为更可持续和高效的工业格局铺平道路。