摩擦学学报
摩抆學學報
마찰학학보
TRIBOLOGY
2001年
3期
191-195
,共5页
张瑞军%李生华%金元生%王玉琮%TUNG Simon C
張瑞軍%李生華%金元生%王玉琮%TUNG Simon C
장서군%리생화%금원생%왕옥종%TUNG Simon C
MoDTC%MoDTP%缸套%活塞环%摩擦磨损
MoDTC%MoDTP%缸套%活塞環%摩抆磨損
MoDTC%MoDTP%항투%활새배%마찰마손
在125 ℃和320 ℃下,以全配方矿物基SJ/5W-30型发动机油作为基础润滑油,考察了油溶性有机钼添加剂MoDTC与MoDTP对灰铸铁缸套/喷钼活塞环摩擦学行为的影响.结果表明:MoDTC可以改善基础油的减摩抗磨性能,而MoDTP仅表现出一定的抗磨作用;试验温度对缸套-活塞环的摩擦磨损性能具有重要影响. X射线光电子能谱分析表明:缸套磨损表面主要含有铁氧化物、氧化钼、硫化铁、二硫化钼以及磷酸盐等,其含量与添加剂类型和摩擦磨损试验温度有关.125 ℃下在缸套磨损表面上减摩组分MoS2和其它耐磨组分的含量较高,这是MoDTC具有较好减摩耐磨性能的主要原因.
在125 ℃和320 ℃下,以全配方礦物基SJ/5W-30型髮動機油作為基礎潤滑油,攷察瞭油溶性有機鉬添加劑MoDTC與MoDTP對灰鑄鐵缸套/噴鉬活塞環摩抆學行為的影響.結果錶明:MoDTC可以改善基礎油的減摩抗磨性能,而MoDTP僅錶現齣一定的抗磨作用;試驗溫度對缸套-活塞環的摩抆磨損性能具有重要影響. X射線光電子能譜分析錶明:缸套磨損錶麵主要含有鐵氧化物、氧化鉬、硫化鐵、二硫化鉬以及燐痠鹽等,其含量與添加劑類型和摩抆磨損試驗溫度有關.125 ℃下在缸套磨損錶麵上減摩組分MoS2和其它耐磨組分的含量較高,這是MoDTC具有較好減摩耐磨性能的主要原因.
재125 ℃화320 ℃하,이전배방광물기SJ/5W-30형발동궤유작위기출윤활유,고찰료유용성유궤목첨가제MoDTC여MoDTP대회주철항투/분목활새배마찰학행위적영향.결과표명:MoDTC가이개선기출유적감마항마성능,이MoDTP부표현출일정적항마작용;시험온도대항투-활새배적마찰마손성능구유중요영향. X사선광전자능보분석표명:항투마손표면주요함유철양화물、양화목、류화철、이류화목이급린산염등,기함량여첨가제류형화마찰마손시험온도유관.125 ℃하재항투마손표면상감마조분MoS2화기타내마조분적함량교고,저시MoDTC구유교호감마내마성능적주요원인.
The tribological behavior of Mo-sprayed piston r ing sliding against grey cast iron cylinder liner under the lubrication of a ful ly formulated petroleum based engine oil SJ/5W-30 containing molybdenum dithioc arbomate (MoDTC) or molybdenum dithiophosphate (MoDTP) was investigated with an Optimol-SRV test rig. The testing temperatures were controlled at 125 ℃ and 32 0 ℃ to simulate the real engine operating conditions.The worn surfaces of the p iston ring and cylinder liner were observed and analyzed by means of scanning el ectron microscopy (SEM) and X-ray photoelectron spectroscopy(XPS). It was obser ved that the frictional behavior of both MoDTC and MoDTP depends heavily on the experimental temperature; MoDTC is effective in decreasing the friction coeffici ent and wear rate at a relatively extended test duration while MoDTP shows frict ion-reduction ability only at relatively high temperatures. It can be seen from the SEM observations of the worn piston ring and cylinder liner surfaces that t he set test temperature range has also strong impact on both the wear severity a nd the wear mechanisms in the contact surface. When it rises from 125 ℃ to 320 ℃, the wear becomes more serious, and the wear mechanism changes from abrasion to adhension. In addition, the chemical interaction between the lubricant conta ining organo-molybdenum and the tribocontact surfaces plays a crucial role in f riction reducing or antiwear film formation, which is dependent on the tribochem ical characteristics of the active ferrous materials and the applied friction mo difiers such as MoDTC or MoDTP. XPS analysis of the worn cylinder liner surfaces indicates that the resultant tribochemical films are mainly composed of iron ox ides, molybdenum oxide, iron sulfide, molybdenum disulfide, and zinc and iron ph osphates. The proportion of these species is a function of both the specific fri ction modifiers used and the experimental temperature. It is supposed that the b etter friction-reduction and wear-resistant actions of MoDTC at 125 ℃ is attr ibuted to the higher content of MoS2 and other wear-resistant compounds gener ated on the worn cylinder liner surfaces.