色呦呦网址在线观看,久久久久久久久福利精品,国产欧美1区2区3区,国产日韩av一区二区在线

The oxidation with temperature in the cutting area can reach 1000°C significantly reduces the hardness and strength of the carbide, greatly shortening the tool’s lifespan and severely affecting the performance of carbide tools. The author of this paper investigates the high-temperature oxidation resistance and high-temperature performance of different carbide compositions, focusing on adjusting the cobalt content, WC grain size, and TaC/NbC/TiC additives. The following conclusions were drawn from this study.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 2

The Effect of Cobalt Content

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 3

Figure 3 shows the microstructure after oxidation of carbides?with different cobalt contents (all WC materials are WC-1). As the cobalt content increases, the microstructure of the carbide?oxides changes significantly. The oxide of the WC-6%Co carbide?has more and larger pores, the pores in the oxide of the WC-10%Co carbide?are significantly reduced, and the oxide of the WC-14%Co carbide?has virtually no large pores.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 4

Figure 4 shows the oxidation weight gain curves of carbides?with different cobalt contents. As the cobalt content increases, the oxidation weight gain of the carbides decreases sequentially. At 900°C, the oxidation weight gain of WC-6%Co, WC-10%Co, and WC-14%Co carbides are 11.92%, 11.46%, and 11.26%, respectively. Compared to WC-6%Co carbide, the oxidation weight gain of WC-10%Co and WC-14%Co carbides?at 900°C decreased by 3.8% and 5.5%, respectively. Therefore, although increasing the Co content can improve the high-temperature oxidation resistance of carbides, the improvement is not significant.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 5

Table 3 lists the oxidation reaction equations of each component in the carbide?and their Gibbs free energy. It is well known that during the oxidation of carbides, the oxidation of WC to WO3 results in significant volume expansion. The oxide WO3 is loose, porous, and volatile, producing volatile gases such as CO2, which provide more pathways for the oxidation diffusion process, thereby exacerbating the oxidation of the carbide. Although the binder phase is more prone to oxidation than the hard phase, the oxide formed from the binder phase is the relatively dense CoWO4, which can slow down the oxidation diffusion process of the carbide. Therefore, with the increase in cobalt content, more CoWO4 and less WO3 are formed, resulting in a denser microstructure of the oxides and consequently improving the high-temperature oxidation resistance of the carbide.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 6

Table 4 shows the room temperature hardness and high-temperature hardness of carbides?with different cobalt contents. At room temperature, the more cobalt content, the lower the hardness of the carbide. When the temperature rises to 800°C, the hardness of the carbides decreases significantly, with the rate of decrease reducing as the cobalt content increases. At 800°C, the hardness of carbides with higher cobalt content is actually higher than that of carbides with lower cobalt content.

 

Both the hard phase and the binder phase exhibit some thermal expansion at high temperatures, with the binder phase experiencing greater thermal expansion and generating larger stress, which offsets some of the load force. This is one of the reasons why the high-temperature hardness of the carbide?increases with the increase in cobalt content.

The Effect of WC Grain Size

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 7

Figure 6 shows the oxidation weight gain curves of 4#, 5#, and 6# carbides?prepared with WC of different Fischer particle sizes. From room temperature to 825°C, the oxidation weight gain curves of the three carbides with different WC grain sizes overlap; however, in the range of 825-900°C, the finer the WC grains, the less the oxidation weight gain of the carbides. At 900°C, the oxidation weight gains of 4#, 5#, and 6# carbides?are 9.18%, 8.67%, and 8.20%, respectively. Compared to the 4# carbide, the oxidation weight gain of the 5# and 6# carbides?at 900°C decreased by 5.6% and 10.7%, respectively. Therefore, under the same Co content, refining the WC grains can improve the high-temperature oxidation resistance of carbides.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 8

Figure 7 shows the XRD diffraction patterns after oxidation of carbides?with different WC grain sizes. Since the compositions of 4#, 5#, and 6# carbides?are the same, there is no significant difference in their oxidation products. Therefore, the diffraction patterns of the oxides of the three carbides?with different WC grain sizes are essentially identical.

 

The Oxidation Resistance and hardness Differences of Carbides with Different WC Grain Sizes

The differences in the oxidation resistance of carbides?with different WC grain sizes can be mainly attributed to the following two points:

In the case of a uniform carbide?structure, finer WC grains result in more phase boundaries between WC and the binder phase. The finer WC grains are better encapsulated by the binder phase, and the oxidation products of the binder phase can, to some extent, hinder the oxidation diffusion process, thereby improving the high-temperature oxidation resistance of the carbide.

Finer WC grains have fewer grain boundary defects and smaller grain boundary voids between the WC grains, which correspondingly reduce the oxidation diffusion channels, thus enhancing the high-temperature oxidation performance of the carbide.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 9

Table 5 shows the room temperature hardness and high-temperature hardness of carbides?with different WC grain sizes. At room temperature, the finer the WC grains, the higher the hardness of the carbide. When the temperature rises to 800°C, the hardness of the carbides decreases significantly, and the rate of decrease in high-temperature hardness increases as the WC grain size decreases. Clearly, although the room temperature hardness of the carbide?increases as the WC grain size decreases, the high-temperature hardness becomes lower.

 

The Effect of TaC/NbC/TiC Additives

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 10

Figure 8 shows the oxidation weight gain curves of carbides?with different carbide additives (all WC materials are WC-3). The oxidation weight gain curves and oxide diffraction patterns of WC-Co and WC-Co-TaC carbides?are basically the same, with oxidation weight gains of 10.58% and 10.20% at 900°C, respectively. Among the four carbides, WC-Co-NbC carbide?has the highest oxidation weight gain, while WC-Co-TiC carbide?has the lowest oxidation weight gain, with oxidation weight gains of 11.68% and 9.05% at 900°C, respectively.

??????

Figure 9 shows the XRD diffraction patterns of carbides?with different carbide additives after oxidation. The oxidation of the carbides produces corresponding oxides.

In WC-Co carbides, the added TaC, NbC, and TiC all exist in the form of W-containing solid solutions. The (Nb,W)C solid solution oxidizes earlier than WC and has many phase boundaries with WC. Without the protective “encapsulation” of the binder phase, the oxidation of the solid solution promotes the oxidation of WC, thereby accelerating the oxidation of the carbide. The oxidation weight gain of WC-Co-TaC carbide?is the same as that of WC-Co carbide. This is because the (Ta,W)C solid solution reacts simultaneously with WC, and since the hard phase WC is the main component, the loose and porous WO3 phase predominantly controls the oxidation rate of the carbide. Therefore, the addition of TaC does not significantly affect the high-temperature oxidation resistance of the carbide.

In summary, under the same conditions of grain size and cobalt content, the addition of TaC has no significant effect on the high-temperature oxidation resistance of the carbide. However, the addition of NbC significantly reduces the high-temperature oxidation resistance of the carbide, with a reduction of 10.4%, while the addition of TiC significantly improves the high-temperature oxidation resistance of the carbide, with an improvement of 14.5%.

The Effects of 3 Elements on the High-Temperature Oxidation Resistance and Hardness of Carbides 11

Table 6 shows the room temperature hardness and high-temperature hardness of carbides?with different carbide additives. At room temperature, the hardness of the carbides with TaC, NbC, and TiC additives is comparable to that of the WC-Co carbide. When the temperature rises to 800°C, the high-temperature hardness of the carbides with TaC, NbC, and TiC additives is higher than that of the WC-Co carbide, and the rate of decrease in high-temperature hardness is significantly reduced.

It is well known that solid solutions exhibit good red hardness and provide structural support to the overall carbide, helping it maintain high hardness under high-temperature conditions. Additionally, the solid solutions contribute to solid solution strengthening of the Co phase, which increases the hardness of the Co phase. Therefore, the addition of TaC, NbC, and TiC results in carbides?exhibiting good high-temperature hardness.

????????

This study investigated the effects of cobalt content, WC grain size, and types of solid solutions on the high-temperature oxidation resistance and high-temperature hardness of carbides. The conclusions are as follows:

1.Increasing the cobalt content improves the high-temperature oxidation resistance of the carbide?and significantly increases the high-temperature hardness.

2.Reducing the WC grain size enhances the high-temperature oxidation resistance of the carbide?but significantly reduces the high-temperature hardness.

3.Compared to WC-Co carbides, the addition of TaC has no significant effect on the high-temperature oxidation resistance of the carbide, the addition of NbC decreases the high-temperature oxidation resistance, and the addition of TiC significantly improves the high-temperature oxidation resistance. All three additives, TaC, NbC, and TiC, significantly enhance the high-temperature hardness of the carbide.

???????????? ??

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

青青草原av青青草原-美日韩精品一区二区三区-中文字幕日本乱码在线-久久热久久热在线视频| 尤物视频在线观看精品-日韩午夜男女爽爽影院-日本少妇下面好紧水多影片-国产亚洲精品视频在线网| 国产一区二区中文字幕在线观看-人妻少妇被粗大爽视频-开心五月婷婷综合网站-国产精品久久国产精麻豆| 日韩亚洲一区二区在线观看-欧美色一区二区三区在线-日韩av黄片在线观看-深夜成人福利在线观看| 18禁无遮挡美女国产-久久精品国产精品亚洲毛片-国内精品极品在线视频看看-日本二区 欧美 亚洲 国产| 国产好大好硬好爽好湿免费视频-国产精品一区二区精品一区二区-白白色发布在线播放国产-99久久国产精品成人观看| 国产亚洲精品首页在线播放-中文字幕国产av中文字幕-日本免费午夜福利视频-亚洲伦理一区二区三区四区| 国产美女口爆吞精服务-亚洲无人区码一码二码三码-久久精品99国产精品最新-日本少妇激情在线视频| 精品国产乱码一二三区在线-精品国产一区二区在线视-国内男女精品一区二区三区-亚洲中文字幕国内精品| 亚洲精品一区二区三区麻豆-国产精品小视频在线看-亚洲国产成人av第一二三区-国产不卡一区二区三区免费视频人| 国产白浆一区二区在线观看-青草衣衣精品国色天香亚洲av-欧美午夜福利性色视频-成人亚洲一区二区三区在线观看| 欧美激情av一区二区三区-美国性感美女抠逼直播视频-亚洲国产精品视频在线播放-日本一高清二区视频久二区| 日本厕所偷拍美女尿尿视频-婷婷国产一区综合久久精品-欧美一日韩成人在线视频-四虎精品视频免费在线观看| 日本很污动漫在线观看-亚洲精品乱码国产精品乱码-日本亚洲一区二区三区四区-少妇高潮太爽了免费观看| 国产一级片内射在线视频-亚洲少妇无套内射激情-成人午夜性色福利视频-夜夜嗨视频无套实战丰满少妇| 麻豆国产av一区二区精品-久久福利社最新av高清精品-丝袜美腿亚洲综合伊人-亚洲欧洲av一区二区三区| 日韩视频精品在线播放-国产91亚洲精品久久-亚欧洲乱码视频在线观看-亚洲国产成人91精品| 日韩黄色精品中文视频-久久精品国产亚洲懂色-欧洲美女日韩精品视频-国产一区二区三区精品愉拍| 亚洲午夜福利在线看片-草草影院在线观看国产-中文字幕在线国产有码-精品99成人午夜在线| 午夜精品人妻一区二区三区-亚洲精品成人久久av-成人亚洲av精品入口-高清传媒视频在线观看| 中文字幕久久精品一区二区三区-99国产麻豆精品人人爱-91麻豆精品福利视频-国产精品亚洲一区中文字幕| 日韩精品极品系列在线免费视频-国产中文字幕有码视频-日韩一区二区免费电影-成人夜晚在线观看视频| 欧美日韩激情片在线观看-色男人天堂网在线观看-亚洲一级特黄大片免色-国产十八禁免费在线观看| 国产欧美日韩精品一区二-久久精品国产精品青草色艺-人妻熟妇视频一区二区不卡-亚洲国产精品第二在线播放| 九九热这里只有精品在线免费视频-色一情一乱一乱一十九区-国产午夜福利视频在线观看-久草免费手机在线视频观看| 亚洲老妈激情一区二区三区-夜晚福利视频亚洲精品自拍视频-亚洲av永久精品一区二区在线-中文国产人精品久久蜜桃| 久久夜色国产精品亚洲-国产视频一区二区三区免费观看-亚洲一区二区成人在线观看-日韩精品一区二区三区在线视频| 日韩色视频免费观看网站大全-免费中文对白国产操片-国产农村妇女一页二页-欧美三级午夜理伦三级在线| 色激情五月关键词挖掘-日本精品一区二区三区视频-亚洲精品一区二区三区四区久久-亚洲综合久久激情久久| 日韩成人动漫视频在线-人妻日韩精品中文字幕-国产老妇伦国产熟女老妇久-久久精品人妻一区二区三区| 国产精品人人爱一区二区白浆-中文字幕一区二区三区人妻精品-91人妻在线欧美精品不卡-好吊视频一区二区三区在线| 岛国精品一区二区三区-国产一区二区三区观看不卡av-四虎三级在线视频播放-亚洲乱妇熟女爽到高潮| 免费手机在线观看bbb视频-国产欧美亚洲精品第1页青草-国产黄a三级三18级三级看三级-宅男视频在线观看一区二区三区| 欧美日韩精品视频免费下载-中文字幕一区二区三区伦理-一级特黄大片亚洲高清-午夜欧美日韩精品久久久久| 日韩免费看在线黄色片-国产精品人妇一区二区三区-国产精品网站一区在线观看-国产精品亚洲一区二区三区不卡| 国产成人高清视频在线观看免费-人妻精品一区二区在线视频-国产成人一区二区三区精品久久-农村肥白老熟妇20p| 亚洲午夜福利在线看片-草草影院在线观看国产-中文字幕在线国产有码-精品99成人午夜在线| 日本老熟妇在线视频网-精品人妻在线一区二区三区视频-91亚洲国产成人精品福利-青青草免费手机直播视频| 中文字幕久久精品一区二区三区-99国产麻豆精品人人爱-91麻豆精品福利视频-国产精品亚洲一区中文字幕| 亚洲av色福利天堂在线观看-人妻少妇午夜福利视频-男人的天堂av在线视频-国内揄拍国产精品人妻一区二区| 久久都是精品久久都是精品-精国精品一区二区成人-亚洲品质自拍在线观看-中文 字幕乱码高清视频|