1) compound modification
复合变质
1.
Effects of compound modification on microstructure of hypereutectic high chromium cast iron;
复合变质对过共晶高铬铸铁凝固组织的影响
2.
Influence of compound modification on the mechanical properties of high silicon alumimum alloy;
复合变质对高硅铝合金力学性能的影响
3.
The effect of addition of Ce and compound modification on microstructure and properties of as-cast Al-21Si-1.
研究了添加Ce与P+Sr复合变质对Al-21Si-1。
2) complex modification
复合变质
1.
Study on complex modification of Al-Mg-Si alloys;
Al-Mg-Si合金的复合变质研究
2.
By means of analysis of microstructure and measuring of impact toughness and hardness,and verification by real manufacture and application,the Si-Mn steel with rare earth and boron complex modification is better than traditional high Mn steel to produce tractor track guard in the wide range of temperature and the low cost and long life.
通过微观组织分析、冲击韧度、硬度等力学性能的测定、实际生产和装车试验证实,采用稀土-硼复合变质的SiMn钢代替传统高锰钢生产拖拉机履带板,不仅使用温度范围广,而且成本低,寿命高,具有明显的经济效益和社会效益。
3.
The results show that the complex modification of P and RE can obviously improve wear resistance of hypereutectic Al-20%Si alloy.
在不同P、RE添加量下对P-RE复合变质和未变质的过共晶铝硅合金的耐磨性进行了研究。
3) composite modification
复合变质
1.
Effects of Composite Modification on the Mechanical Properties of ZL101 Alloy;
复合变质对ZL101合金力学性能的影响
2.
The Al-Si-Mg alloy was cooled and solidified under the different condition of air, water and liquid nitrogen after composite modification by the addition of the refiner (Al-1Ti-1B or Al-3Ti-3B master alloy) and the modification agent (Al-9Sr master alloy).
Al-Si-Mg合金通过加入细化剂Al-1Ti-1B中间合金或细化剂Al-3Ti-3B中间合金及变质剂Al-9Sr中间合金进行复合变质后,分别在空气中、水中和液氮中冷却凝固。
3.
The influences of composite modification order with phosphor and rare earth on the microstructure of hypereutectic A1-24%Si alloy were investigated,the composite modification mechanism was discussed.
研究了磷、稀土复合变质剂的加入顺序对过共晶Al-24%Si合金的影响,同时探讨了复合变质机制。
4) modification
[英][,mɔdɪfɪ'keɪʃn] [美]['mɑdəfə'keʃən]
复合变质
1.
Effects of RE multiple modification on the structure of super-high manganese steel;
稀土复合变质对超高锰钢组织的影响
2.
By means of the modification of RE-Al-Ti-C compound,the eutectic structure of the steel is refined and the amount of divorced eutectic increases.
经RE-Al-Ti-C复合变质剂变质处理后,其共晶组织发生细化,离异共晶数量增多;经热处理后,其碳化物变成粒状且均匀分布于基体中,冲击韧度得到明显提高。
5) composite modifier
复合变质剂
1.
Effect of RE-Mg composite modifier on purification and modification of meta bainitic cast steel;
RE-Mg复合变质剂对准贝氏体铸钢的净化与变质作用
2.
The results have shown that the morphology of the eutectic carbides in the W_(18)Cr_4V hardfacing alloy treated with the appropriate RE-Mg composite modifier additive changed from continuous network to isolated, fine and irregular blocks and the impact toughness and abrasion resistance increased accordingly.
采用H08A作焊芯,通过焊条药皮过渡W、Cr及V等合金元素,研究出具有优良抗磨耐热性能的堆焊焊条,并对稀土镁复合变质剂的作用进行分析与讨论。
3.
The effect of REAlTiBP multicomponent composite modifier to alloy structure and property of cast aluminum 117 was studied.
研究了REAlTiBP多元复合变质剂对ZL117合金组织和性能的影响。
6) compound modificator
复合变质剂
1.
The effects of compound modificator on microstructure,mechanical properties,wearing properties and damping properties of ZA27 alloy have been studied.
研究了复合变质剂对ZA2 7合金组织、力学性能、耐磨性和阻尼性能的影响。
2.
In this paper the effects of the Re K Zn compound modificator on the microstructure and properties of high Chromium white cast iron as cast have been studied by the method of orthogonal design.
本文通过正交设计实验研究了Re K Zn复合变质剂对高铬白口铸铁组织和性能的影响 ,借助于电子扫描显微镜、X 射线能谱仪等先进设备对其影响结果进行了分析。
补充资料:复合材料的复合效应
复合材料的复合效应
composition effect of composite materials
复合材料的复合效应Composition effeet of Com-Posite materials复合材料特有的一种效应,包括线性效应和非线性效应两类。 线性效应包括平均效应、平行效应、相补效应和相抵效应。例如常用于估算增强体与基体在不同体积分数情况下性能的混合率,即 Pc一巧几+VmPm式中Pc为复合材料的某一性质,乃、几分别为增强体和基体的这种性质,VR、Vm则分别是两者的体积分数。这就是基于平均效应上的典型事例。另外关于相补效应和相抵效应,它们常常是共同存在的。显然,相补效应是希望得到的而相抵效应要尽可能避免,这个可通过设计来实现。 非线性效应包括乘积效应、系统效应、诱导效应和共振效应、其中有的己经被认识和利用,并为功能复合材料的设计提供了很大自由度;而有的效应则尚未被充分地认识和利用。乘积效应即已被用于设计功能复合材料。如把一种具有两种性能互相转换的功能材料X/y(如压力/磁场换能材料)和另一种Y/Z的换能材料(如磁场/电阻换能材料)复合起来,其效果是(X/D·(Y/Z)二X/Z,即变成压力/电阻换能的新材料。这样的组合可以非常广泛(见表)。系统效应的机理尚不很清楚,但在实际现象中已经发现这种效应的存在。例如交替迭层镀膜的硬度远大于原来各单一镀膜的硬度和按线性棍合率估算的数值,说明组成了复合系统才能出现的性质。诱导行为已经在很多实验中发现,同时这种效应也在复合材料的乘积效应┌──────┬──────┬──────────┐│甲相性质 │乙相性质 │复合后的乘积性质 ││ X/y │ Y/Z │沙到豹·(Y/公一义您 │├──────┼──────┼──────────┤│压磁效应 │磁阻效应 │压敏电阻效应 │├──────┼──────┼──────────┤│压磁效应 │磁电效应 │压电效应 │├──────┼──────┼──────────┤│压电效应 │场致发光效应│压力发光效应 │├──────┼──────┼──────────┤│磁致伸缩效应│压阻效应 │磁阻效应 │├──────┼──────┼──────────┤│光导效应 │电致效应 │光致伸缩 │├──────┼──────┼──────────┤│闪烁效应 │光导效应 │辐射诱导导电 │├──────┼──────┼──────────┤│热致变形效应│压敏电阻效应│热敏电阻效应 │└──────┴──────┴──────────┘复合材料界面的两侧发现,如诱导结晶或取向,但是尚未能利用这种效应来主动地设计复合材料。两个相邻的物体在一定的条件下会产生机械的或电、磁的共振,这是熟知的物理行为。复合材料是多种材料的组合,如果加以有目的性的设计,肯定可利用这种共振效应,但是目前尚未加以研究。(吴人洁)
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条