carbide

简明释义

英[/ˈkɑːr.baɪd/]美[/ˈkɑːr.baɪd/]

[无化] 碳化物

英英释义

单词用法

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例句

1.At this time, plasma treatment, the removal of carbide declare in no uncertain terms to take responsibility.

此时，等离子体处理技术，毫不讳言地担当其了除去碳化物的重任。

2.For carbide glass ceramics stone precious stones and other heavy-load cutting grinding wear resistance.

用于硬质合金、玻璃、陶瓷、石材、宝石等重负荷切割、磨削耐磨性好。

3.Step 4 - the background is then stippled with a carbide tool sharpened to a needle point.

步骤4-背景，然后用削尖的点画到一个针尖一硬质合金工具。

4.The wreckage of the Union Carbide pesticide plant continues to leach deadly chemicals into the water supply.

联合碳化物公司的农药厂残骸仍在继续向城市供应用水渗入致命的化学成分。

5.The feature of machining harden steel by means of EHM are: it can utilize the carbide tool to machine the harden steel in engine lathe.

采用导电加热切削技术切削淬硬钢的特点在于：可以采用普通机床、硬质合金刀具对淬硬钢进行硬车削加工。

6.For extra durability it features carbide diff balls and a titanium nitride-coated diff screw.

为额外的耐用性，它的特点碳化物差异球和氮化钛涂层差异螺钉。

7.Our goal is: Does China's most professional manufacturer of Carbide Tools!

我们的目标是：做中国最专业的硬质合金刀具生产商！

8.ALLOY steel: a steel containing iron and carbide plus one or more other metals such as nickel, chromium, or molybdenum.

合金钢：指钢中含有铁，碳，以及镍、铬、钼等一种或多种其他的合金元素。

9.It provides higher abrasion resistance compared to tungsten carbide at the expense of some toughness.

它提供了更高的耐磨性比钨在硬质合金牺牲一些韧性。

10.The cutting tool is made from high-speed carbide.

这个切削工具是由高速碳化物制成的。

11.We use carbide inserts for machining hard materials.

我们使用碳化物刀片来加工硬材料。

12.The carbide tips on the drill provide better durability.

钻头上的碳化物尖端提供更好的耐用性。

13.Welding carbide can improve the wear resistance of tools.

焊接碳化物可以提高工具的耐磨性。

14.The production of carbide requires high temperatures.

生产碳化物需要高温。

作文

Carbide is a fascinating compound that plays a crucial role in various industrial applications. It is formed by the chemical combination of carbon with a less electronegative element, typically a metal. The most well-known type of carbide is tungsten carbide, which is renowned for its exceptional hardness and durability. This unique property makes it an ideal material for cutting tools, mining equipment, and other applications where wear resistance is essential. In this essay, we will explore the significance of carbide (碳化物) in modern industries, its various types, and its future prospects. One of the primary uses of carbide (碳化物) is in the manufacturing of cutting tools. Tungsten carbide, for instance, is used to create drill bits, saw blades, and milling cutters. These tools are essential in construction, manufacturing, and metalworking industries, where precision and durability are paramount. The hardness of tungsten carbide allows these tools to cut through tough materials like steel, making them indispensable in high-performance machining operations. Furthermore, the ability to withstand high temperatures without losing their hardness gives carbide (碳化物) tools a significant advantage over traditional steel tools. Apart from cutting tools, carbide (碳化物) has found applications in the production of abrasives. Abrasive materials are used for grinding, polishing, and surface finishing. Silicon carbide, another form of carbide (碳化物), is commonly used in sandpaper and grinding wheels due to its sharpness and durability. The use of carbide (碳化物) abrasives enhances productivity in various industries by providing superior performance compared to conventional materials. The automotive industry also benefits from the properties of carbide (碳化物). Carbide inserts are often used in engine components, such as valves and pistons, due to their ability to withstand high temperatures and pressures. This application not only improves the efficiency and longevity of engines but also contributes to the overall performance of vehicles. As the demand for more efficient and durable automotive parts increases, the role of carbide (碳化物) in this sector is expected to grow. In the field of electronics, carbide (碳化物) is gaining attention for its potential use in semiconductor technology. Silicon carbide (SiC) is being researched for its ability to handle high voltages and temperatures, making it suitable for power electronics and high-frequency devices. The transition from traditional silicon-based semiconductors to carbide (碳化物) could lead to more efficient energy systems and advanced electronic devices, paving the way for innovations in renewable energy and electric vehicles. As we look toward the future, the demand for carbide (碳化物) is likely to increase. With ongoing advancements in technology and materials science, new forms of carbide (碳化物) may emerge, offering even greater performance and versatility. Researchers are exploring ways to enhance the synthesis and processing of carbide (碳化物) materials to create composites that can withstand extreme conditions, further expanding their applications. In conclusion, carbide (碳化物) is an essential material that significantly impacts various industries, from manufacturing to electronics. Its remarkable properties, such as hardness, durability, and heat resistance, make it invaluable in creating tools, abrasives, and components that enhance productivity and performance. As technology continues to evolve, the role of carbide (碳化物) will undoubtedly expand, leading to new innovations and applications that can benefit society as a whole.