pelleting

简明释义

英[ˈpelɪtɪŋ]美[ˈpelɪt]

n. 造粒；[机]粒化

v. 使形成小球；用子弹射击（pellet 的 ing 形式）

英英释义

单词用法

同义词

反义词

例句

1.In this paper, the pelleting methods of natural apatite and the influencing factors are investigated.

探讨了改性天然磷灰石废水处理剂的造粒方法及其影响因素。

2.Both the experiment of pelleting technology and the seeding test of pelleting cottonseed showed that the technology is feasible.

通过丸粒化工艺试验和丸粒化棉种种植试验，证明这一加工工艺可行。

3.Applicable to the fine grinding of alfalfa prior to pelleting.

适用于苜蓿草制粒前的细粉碎。

4.So that, it is necessary to adopt very sinterable UO2 powder and suitable pelleting and sintering conditions to minimize open porosity and small porosity.

因此，必须采用烧结性良好的UO_2粉末和合适的成型烧结条件以使开口孔隙度和细孔隙度降至最低。

5.In addition, the relationships between conditioning temperature and pelleting temperature, between steam pressure and pelleting temperature as well as conditioning moisture were analyzed.

另外，分析了调质温度与制粒温度，蒸汽压力与制粒温度及调质水分之间的关系。

6.The wet coupling method is better but more troublesome than the dry method and transfering method, and it can be conveniently carried out during the pelleting of whiskers.

湿法偶联效果较干法与迁移法好，但过程较繁，适宜于在晶须造粒时同时完成湿法偶联。

7.Powder material pelleting.

粉体物料制丸。

8.Particularly it is suitable for granulating, pelleting and coating of various varieties in pharmaceutical industry, foodstuff industry and chemical industry, etc.

特别适用于医药、食品、化工等行业多品种、多剂型制粒、制丸及包衣。

9.The process of pelleting is essential in the production of animal feed.

在动物饲料生产中，颗粒化过程是至关重要的。

10.Many manufacturers use pelleting to create uniform feed sizes.

许多制造商使用颗粒化来创建均匀的饲料尺寸。

11.The pelleting of biomass can improve its transportability.

生物质颗粒化可以提高其运输性。

12.During the pelleting process, steam is often applied to enhance binding.

在颗粒化过程中，通常会施加蒸汽以增强粘合性。

13.The quality of pelleting affects the digestibility of the feed.

颗粒化的质量会影响饲料的消化率。

作文

In the modern world of manufacturing and agriculture, the process of pelleting (造粒) has become increasingly important. This technique involves compressing materials into small, dense pellets, which can be utilized in various industries such as animal feed production, pharmaceuticals, and even biofuels. The significance of pelleting (造粒) lies in its ability to enhance the efficiency of material handling, improve storage capabilities, and facilitate easier transportation. To understand the mechanics of pelleting (造粒), it is essential to recognize the materials involved. In animal nutrition, for instance, raw ingredients such as grains, proteins, and vitamins are often mixed together before undergoing the pelleting (造粒) process. This mixture is then subjected to high pressure and temperature in a pellet mill, which forces the materials through a die, shaping them into uniform pellets. These pellets not only ensure that animals receive a balanced diet but also reduce waste and improve feed conversion ratios. The benefits of pelleting (造粒) extend beyond just animal feed. In the pharmaceutical industry, pelleting (造粒) is used to create controlled-release medications. By forming pellets with specific coatings, manufacturers can regulate the release of active ingredients, ensuring that patients receive their medication over an extended period. This method enhances the effectiveness of treatments while minimizing side effects. Moreover, pelleting (造粒) plays a crucial role in the production of biofuels. Biomass materials, such as wood chips, agricultural residues, and other organic matter, are often converted into pellets for easier combustion. The process of pelleting (造粒) increases the energy density of these materials, making them more efficient for transport and storage. As the world continues to shift towards renewable energy sources, the demand for pelleting (造粒) technologies is expected to grow significantly. Despite its many advantages, the pelleting (造粒) process is not without challenges. One major concern is the energy consumption associated with producing pellets. The high temperatures and pressures required can lead to significant energy costs, prompting researchers to explore more sustainable methods. Innovations in equipment design and alternative energy sources are being investigated to reduce the carbon footprint of pelleting (造粒). Additionally, the quality of the final pellets is paramount. Factors such as moisture content, particle size, and the presence of additives can all influence the integrity of the pellets. Manufacturers must carefully monitor these variables to ensure that the pellets produced meet industry standards and consumer expectations. Quality control measures during the pelleting (造粒) process are essential to maintain consistency and reliability. In conclusion, the process of pelleting (造粒) is a vital component in various sectors, from agriculture to pharmaceuticals and renewable energy. Its ability to convert raw materials into efficient, manageable forms has revolutionized how we approach manufacturing and resource utilization. As technology advances and sustainability becomes a priority, the future of pelleting (造粒) looks promising, with opportunities for innovation and improvement. Understanding this process is crucial for anyone involved in these industries, as it holds the key to enhancing productivity and meeting the demands of a growing global population.