sintering

简明释义

[ˈsɪntərɪŋ][ˈsɪntərɪŋ]

n. 烧结

v. 烧结;使熔结(sinter 的 ing 形式)

adj. 烧结的

英英释义

Sintering is a process used to create solid materials from powders by applying heat without melting the material, allowing particles to adhere to each other.

烧结是一种通过加热粉末而不熔化材料来制造固体材料的过程,使颗粒相互粘合。

单词用法

sintering process

烧结法,烧结过程

sintering temperature

烧结温度;软化温度

同义词

fusing

熔合

The fusing of powders at high temperatures can create strong materials.

在高温下粉末的熔合可以产生强度材料。

bonding

粘结

Bonding techniques are essential in ceramics manufacturing.

粘结技术在陶瓷制造中至关重要。

compacting

压实

Compacting the material before sintering improves its density.

在烧结前对材料进行压实可提高其密度。

pelletizing

造粒

Pelletizing is often a pre-treatment step before sintering.

造粒通常是烧结前的预处理步骤。

反义词

melting

熔化

The metal will melt at high temperatures.

金属在高温下会熔化。

dissolving

溶解

Salt dissolves in water.

盐在水中溶解。

例句

1.Sintering Machine design paperless design will greatly reduce the workload of workers.

烧结机的无纸化设计将大大减轻设计工作者的工作量。

2.The processes of rapid forming solid parts by laser sintering ceramic powder include laser sintering and second sintering post treatment.

激光烧结陶瓷粉末快速成型三维零件的过程包括激光烧结和二次烧结后处理两个步骤。

3.Hot pressed sintering can shorten sintering time and be beneficial to attain nano grain size sintering materials.

热压烧结可以缩短烧结时间,有利于获得晶粒保持纳米尺度的烧结体材料。

4.Spark plasma sintering (SPS) is a new process of rapid sintering.

放电等离子烧结(SPS)是一种快速烧结新工艺。

5.Therefore, these results prove that crystal formation interferes with the sintering process of a crystalline frit .

所以这些结果证明晶体结构干扰结晶弗里茨的烧结过程。

6.WC powders prepared at higher temperatures are characterized by complete sintering, coarse substructure and slight micro-strain.

在高温下制取的wc粉,结晶完整,晶内亚结构粗大,微观应变小。

7.Ceramic elements are made by pressing and sintering finely powdered materials.

陶瓷元件是将仔细研磨的材料经过加压和烧结制成的。

8.His team at Loughborough University has invented a high-speed sintering system.

在Loughborough大学,他的团队已经创造了一套快速烧结系统。

9.Instead, "sintering" or "firing" is the process typically used.

作为替代,一般采用“烧结”或“焙烧”工艺。

10.The process of sintering is essential for creating strong ceramic materials.

过程中的烧结对制造坚固的陶瓷材料至关重要。

11.Researchers are studying the effects of different atmospheres on the sintering process.

研究人员正在研究不同气氛对烧结过程的影响。

12.In metalworking, sintering helps to bond powders into a solid piece.

在金属加工中,烧结有助于将粉末结合成一个固体件。

13.The sintering temperature must be carefully controlled to achieve the desired properties.

必须仔细控制烧结温度,以达到所需的性能。

14.Additive manufacturing often utilizes sintering to create complex geometries.

增材制造通常利用烧结来创建复杂的几何形状。

作文

Sintering is a fascinating process that plays a crucial role in the manufacturing of various materials, particularly in the field of ceramics and metals. The term sintering (烧结) refers to the method of compacting and forming a solid mass of material by heat or pressure without melting it to the point of liquefaction. This technique is widely used in industries ranging from electronics to automotive, where high-performance materials are essential. The basic principle of sintering (烧结) involves heating powdered materials to a temperature below their melting point, causing the particles to bond together. During this process, the individual particles undergo a transformation; they begin to fuse at their contact points, leading to a denser and stronger material. The effectiveness of sintering (烧结) can be influenced by several factors, including temperature, time, and the nature of the materials being used. One of the most significant advantages of sintering (烧结) is its ability to produce complex shapes that would be difficult or impossible to achieve through traditional casting methods. For example, in the production of metal components, sintering (烧结) allows for the creation of intricate designs with precise dimensions. This not only enhances the performance of the final product but also reduces waste, as excess material is minimized during the manufacturing process. In the ceramics industry, sintering (烧结) is essential for producing items such as tiles, bricks, and porcelain. The process helps to improve the mechanical properties of these materials, making them more durable and resistant to wear and tear. Additionally, sintering (烧结) can enhance the aesthetic qualities of ceramics, allowing for a variety of textures and finishes that appeal to consumers. Furthermore, sintering (烧结) has applications in advanced technologies, including the production of semiconductors and other electronic components. In these fields, the precision and reliability of materials are paramount. The controlled environment of the sintering (烧结) process ensures that the final products meet strict quality standards, which is essential for the performance of electronic devices. However, it is important to note that sintering (烧结) is not without its challenges. Achieving the optimal parameters for the process can require extensive experimentation and expertise. Factors such as particle size distribution, the presence of additives, and the atmosphere in which sintering (烧结) occurs can all influence the outcome. As a result, ongoing research is focused on improving sintering (烧结) techniques to enhance efficiency and reduce costs. In conclusion, sintering (烧结) is a vital manufacturing process that significantly impacts various industries. Its ability to create high-quality materials with complex shapes makes it an indispensable technique in modern manufacturing. As technology continues to advance, the role of sintering (烧结) will likely expand, leading to even more innovative applications and improved material properties. Understanding the intricacies of sintering (烧结) not only enriches our knowledge of material science but also highlights the importance of this process in shaping the future of manufacturing.