欧美人妻精品一区二区三区99,中文字幕日韩精品内射,精品国产综合成人亚洲区,久久香蕉国产线熟妇人妻

In recent years, the production technology of ultra-fine grain cemented carbide has developed rapidly, especially in the key technology of preparing ultra-fine grain WC powder, where the competition is very fierce. Many promising methods have emerged, some of which have reached the level of practical application. However, there are few reports in domestic literature, especially on basic theories or regularity research. In the process of developing the preparation technology of ultra-fine grain WC powder, this paper deeply investigates the influence of the particle size of carbon black powder on the carbon content of WC powder under different carbonization temperatures when using ultra-fine (0.35 μm) tungsten powder.

 

The Influence of Carbon Black Particle Size on the Carbon Content of WC Powder 2

Experimental Content and Method

Test Materials of WC powder

(1) Ultra-fine tungsten powder: The ultra-fine tungsten powder is prepared by the ultrasonic spray pyrolysis method from ultra-fine WO? powder, which is generally amorphous with an average particle size of 25~30 nm. It is reduced by hydrogen at a medium temperature (750~780℃) to obtain tungsten powder with an average particle size of ≤0.35μm (BET particle size).

(2) Carbon black powder: Carbon black powder is produced by two methods: one is by cracking ethane and propane (at 850℃) and then subjected to high-energy ball milling for different periods to produce carbon black powders with average particle sizes of 0.1 and 0.3 μm, respectively; the other is from activated carbon powder with an original particle size of 100~200μm, which is subjected to high-energy ball milling for different periods to produce carbon black powders with average particle sizes of 0.8 and 4.5 μm, respectively.

Experimental Method

Using ultra-fine tungsten powder with the same particle size (0.35 μm) and four different particle sizes (0.1, 0.3, 0.8, 4.5 μm) of carbon black powder, the carbon is blended according to the reaction formula W+C=WC (with an additional loss of 0.1%). The mixture is ball milled for 1.5 hours in a conventional ball mill with a ball-to-material ratio of 1:1. The heat-resistant stainless steel boat containing the mixed material is placed in a stainless steel tube furnace and carbonized under a hydrogen atmosphere. The holding time is 40 minutes for all. In the temperature range of 830~1300℃, the carbonized material is taken out at different temperatures, cooled, and then removed from the furnace. Subsequently, XRD phase analysis and chemical analysis are conducted to determine the total carbon and free carbon, and the amount of combined carbon in WC is calculated. Finally, the quantitative relationship between the particle size of carbon black powder and the phase composition and combined carbon content of WC powder under different carbonization temperatures can be plotted.

 

Test Results and Discussion

Figure 1 shows the effect of carbon black powder with different particle sizes carbonized at different temperatures on the combined carbon content of WC powder. Curve 1 in Figure 1 represents the relationship between carbonization temperature and the combined carbon content of WC powder when using ultra-fine carbon black powder with a particle size of 0.1 μm. As can be seen from Figure 1, when using 0.1 μm ultra-fine carbon black, the combined carbon content of WC powder can reach 5.8% (by mass), which is equivalent to 95% of the theoretical content, at a very low carbonization temperature (850℃). When the temperature is greater than 950℃, the carbon content of WC powder can reach the theoretical content. This result indicates that the carbonization reaction can be completed at a low temperature when using ultra-fine tungsten powder in conjunction with ultra-fine carbon black powder. This phenomenon suggests that the ultra-fine W powder particles are carbonized before they undergo significant aggregation and growth.

The Influence of Carbon Black Particle Size on the Carbon Content of WC Powder 3
At this temperature, as the particle size of the carbon black used increases, the combined carbon content in WC powder rapidly decreases. For example, as shown in Curve 2 of Figure 1, when using 0.3 μm carbon black at 950℃ with the same holding time of 40 minutes, the combined carbon content of WC powder only reaches 5.2% (by mass). XRD analysis indicates that there is still significant W?C in the WC powder, as shown in Figure 2. The free carbon phase was not detected due to its low content. The combined carbon content in WC powder can only reach the theoretical value when the temperature is increased to 1060℃. Its complete carbonization temperature is about 130℃ higher than that of the 0.1 μm carbon black.

????? ??? ?????? ??????? ?????? ??? ????? ??????? ?? ????? WC 4

When using 0.8 μm carbon black, as shown in Curve 3 of Figure 1, at 950℃ with a holding time of 40 minutes, the combined carbon content of WC is only 3.18% (by mass). XRD analysis indicates that in addition to the obvious W?C phase, there is also significant free carbon present in the WC powder, as shown in Figure 3. The combined carbon content in WC powder can only reach the theoretical value when the carbonization temperature is increased to 1230℃. The temperature required for complete carbonization has increased significantly.
The reason for this phenomenon is that when the carbon content ratio is constant, the finer the carbon black particle size, the easier it is to mix uniformly with W powder particles, increasing the contact area between them. Undoubtedly, fine-grained carbon black will accelerate the carbonization rate. Moreover, the finer the carbon black particle size, the more its specific surface area and the number of active carbon atoms on the surface increase dramatically. Thus, the carbonization reaction rate between carbon and tungsten accelerates, and the complete carbonization temperature decreases with the decrease of carbon black particle size.

WC powder

Conclusions

(1) When the particle size of ultra-fine W powder is the same (≤0.35μm), the combined carbon content in WC powder decreases significantly with the increase of the carbon black particle size at a certain temperature.
(2) When the particle size of carbon black is constant, the content of combined carbon increases with the rise of carbonization temperature.

???? ???????

?? ??? ??? ????? ????? ??????????. ?????? ????????? ???? ????? ?? *

无码av一区二区大桥久未| 欧美亚洲熟妇视频在线观看| 国产合区在线一区二区三区| 激情亚洲人妻精品| 高颜值美女视频在线观看| 国产熟女露脸普通话对白| 几把日逼嗯嗯视频| 爱爰哦好粗好猛操b视频| 三级无码日B视频| 国产精品碰碰现在自| 中日韩VA无码中文字幕| 久久精品欧美日韩精品不卡| 亚洲av 又黄又爽十大| 男人的下面进女人的下面在线观看| 大胸美女被c的嗷嗷叫视频| 亚洲欧美国产原创一区二区三区| 差鸡巴没码在线观看| 国产精品亚洲一区二区三区下载| 男人草女人的骚逼逼| 火辣美女的操大逼| 亚洲国产日韩欧美高清片| 老司机午夜精品视频无码| 美女被插b在线观看| 美性中文网中文字幕91| 91精品捆绑蜜桃| 啊啊好想被大鸡巴操视频| 美女亚洲福利视频| 日韩午夜免费av在线| 女人182毛片a级毛片| 日韩欧美综合一二三区| 99热这里只有精品97| 黄色软件大屌怒戳粉嫩小穴| 国产一区二区三区 韩国女主播| 亚洲欧美日韩中文v在线| 久久久久亚洲精品无码系列| 亚洲国产AV精品一区二区色欲| 制服丝袜国产在线第一页| ai换脸久久一区二区亚洲av| 日本高清一区二区三区水蜜桃| 骚女性爱视频在线看| 黑人妖大鸡吧操逼|