thermoplastic n.

简明释义

热塑性热塑性塑料a.热塑的

英英释义

例句

1.Many toys are manufactured using thermoplastic n. due to its safety and ease of molding.

许多玩具采用热塑性塑料 n.制造，因为它安全且易于成型。

2.The recycling process for thermoplastic n. is simpler compared to thermosetting plastics.

与热固性塑料相比，热塑性塑料 n.的回收过程更简单。

3.In construction, thermoplastic n. is used for pipes and fittings because of its resistance to corrosion.

在建筑中，热塑性塑料 n.用于管道和配件，因为它耐腐蚀。

4.The new product is made from a durable thermoplastic n. which allows for flexibility and resilience.

新产品由一种耐用的热塑性塑料 n.制成，具有灵活性和韧性。

5.The automotive industry increasingly relies on thermoplastic n. materials for lightweight components.

汽车工业越来越依赖于热塑性塑料 n.材料来制造轻量化部件。

作文

In the world of materials science, understanding the properties and applications of various substances is crucial. One such material that has gained significant attention in recent years is thermoplastic n.. A thermoplastic n. is a type of polymer that becomes pliable or moldable upon heating and solidifies upon cooling. This unique characteristic makes thermoplastic n. materials incredibly versatile and widely used in various industries, including automotive, packaging, and consumer goods.The process of molding thermoplastic n. materials is relatively straightforward. When heated, they can be shaped into different forms, allowing manufacturers to create complex designs with ease. Once cooled, these materials retain their new shape, making them ideal for mass production. For instance, common items like plastic bottles, containers, and even parts of cars are often made from thermoplastic n. materials due to their durability and lightweight nature.One of the most significant advantages of thermoplastic n. is its recyclability. Unlike thermosetting plastics, which cannot be remolded after curing, thermoplastic n. can be reheated and reshaped multiple times without losing its integrity. This property not only contributes to sustainability efforts by reducing waste but also allows manufacturers to utilize recycled materials in their production processes. As environmental concerns continue to rise, the demand for thermoplastic n. materials is expected to increase as companies seek more sustainable alternatives.Moreover, the range of thermoplastic n. materials available is vast. Some common types include polyethylene (PE), polypropylene (PP), and polyvinyl chloride (PVC). Each of these materials possesses unique properties that make them suitable for specific applications. For example, polyethylene is known for its flexibility and resistance to moisture, making it a popular choice for packaging. On the other hand, polypropylene offers higher melting points and chemical resistance, making it ideal for automotive components.In addition to their practical uses, thermoplastic n. materials are also being explored for innovative applications in fields such as medicine and electronics. Researchers are investigating the use of thermoplastic n. polymers in 3D printing technology, which allows for the creation of customized medical devices and prosthetics. This advancement could revolutionize the way we approach healthcare, providing tailored solutions for patients in need.As we look to the future, the role of thermoplastic n. in our daily lives will likely expand. With ongoing research and development, new formulations and applications are continually emerging. The ability to combine thermoplastic n. with other materials can lead to enhanced performance characteristics, opening doors to new possibilities in product design and functionality.In conclusion, thermoplastic n. materials play a vital role in modern manufacturing and product design. Their unique properties, such as moldability, recyclability, and versatility, make them an essential component in various industries. As we continue to innovate and prioritize sustainability, the importance of thermoplastic n. is bound to grow, shaping the future of materials science and engineering. Understanding and harnessing the potential of thermoplastic n. will undoubtedly lead to exciting advancements that benefit both consumers and the environment.

在材料科学的世界中，理解各种物质的特性和应用至关重要。其中一种近年来备受关注的材料是热塑性塑料 n.。热塑性塑料 n.是一种聚合物，受热后变得可塑或可模制，冷却后固化。这种独特的特性使得热塑性塑料 n.材料极为多功能，并广泛应用于汽车、包装和消费品等多个行业。模制热塑性塑料 n.材料的过程相对简单。当加热时，它们可以被塑造成不同的形状，使制造商能够轻松创建复杂的设计。一旦冷却，这些材料保持其新形状，非常适合大规模生产。例如，常见的塑料瓶、容器甚至汽车部件通常由热塑性塑料 n.材料制成，因为它们耐用且重量轻。热塑性塑料 n.的一大显著优势是其可回收性。与热固性塑料不同，后者在固化后无法重新模制，热塑性塑料 n.可以多次加热和重新塑形，而不会失去其完整性。这一特性不仅有助于通过减少废物来支持可持续发展努力，还允许制造商在生产过程中利用回收材料。随着环境问题的不断上升，对热塑性塑料 n.材料的需求预计将增加，因为公司寻求更可持续的替代品。此外，热塑性塑料 n.材料的种类繁多。一些常见类型包括聚乙烯（PE）、聚丙烯（PP）和聚氯乙烯（PVC）。每种材料都具有独特的特性，使其适用于特定应用。例如，聚乙烯以其灵活性和耐潮湿性而闻名，是包装的热门选择。而聚丙烯则提供更高的熔点和化学抵抗力，非常适合汽车部件。除了实际用途外，研究人员还在探索热塑性塑料 n.材料在医学和电子领域的创新应用。他们正在研究在3D打印技术中使用热塑性塑料 n.聚合物，这使得定制医疗设备和假肢的创建成为可能。这一进展可能会彻底改变我们对医疗保健的看法，为需要帮助的患者提供量身定制的解决方案。展望未来，热塑性塑料 n.在我们日常生活中的角色可能会不断扩大。随着持续的研究和开发，新配方和应用不断涌现。将热塑性塑料 n.与其他材料结合的能力可以带来增强的性能特征，为产品设计和功能开辟新的可能性。总之，热塑性塑料 n.材料在现代制造和产品设计中发挥着至关重要的作用。它们独特的特性，如可模塑性、可回收性和多功能性，使其成为各个行业的重要组成部分。随着我们继续创新和优先考虑可持续性，热塑性塑料 n.的重要性必将增长，塑造材料科学和工程的未来。理解和利用热塑性塑料 n.的潜力无疑将导致令人兴奋的进展，造福消费者和环境。