The accuracy(repeatability and reproducibility) of the iron content analysis of galvanized coating using an X-ray fluorescence spectrometer with an L-spectrum is not better than that of flame atomic absorption spectro...The accuracy(repeatability and reproducibility) of the iron content analysis of galvanized coating using an X-ray fluorescence spectrometer with an L-spectrum is not better than that of flame atomic absorption spectrometry, sometimes it exceeds the quality control limit.Influences, such as current, voltage, equipment(internal circulating water, 10%CH4+90%Ar, and vacuum) checking, instrument monitoring, sample cleaning, and oper-ators, were investigated by means of 6-sigma and lean operations to improve accuracy.展开更多
The microstructure of hot-dip galvanized Zn-ll%A1-3%Mg-0.270Si alloy coating was studied in this article. X-ray diffraction analysis revealed the coating is composed by Zn, A1 and MgZn2 phase. Optical microscope (OM...The microstructure of hot-dip galvanized Zn-ll%A1-3%Mg-0.270Si alloy coating was studied in this article. X-ray diffraction analysis revealed the coating is composed by Zn, A1 and MgZn2 phase. Optical microscope (OM) and scanning electron microscope (SEM) observations showed the coating is occupied by snowflake-like dendrite, double hexagonal organization and eutectic. The coating backbone was the dendrite considered to be a phase of hexagonal close-packed (HCP) structure judging form its morphology according to the crystal growth way in the coating. Transmission electron microscopy (TEM) and energy dispersive spectroscopy (EDS) researches on the dendrite suggested that an intermediate Zn-A1 phase was formed at high temperature, then decomposed into a type of Zn-A1 granular eutectoid after cooling down to room temperature, while the eutectoid Zn and A1 had a certain crystallographic relationship. The coating solidification process and the grain crystal structure were discussed.展开更多
Ti–Al mixed powder(Ti:Al = 3:1 in atomic ratio) and Ti3 Al intermetallic alloy powder mechanically clad hexagonal BN to fabricate Ti Al/BN and Ti3Al/BN composite powders. The corresponding porous abradable seal c...Ti–Al mixed powder(Ti:Al = 3:1 in atomic ratio) and Ti3 Al intermetallic alloy powder mechanically clad hexagonal BN to fabricate Ti Al/BN and Ti3Al/BN composite powders. The corresponding porous abradable seal coatings(named as TAC-1 and TAC-2, respectively) were deposited using vacuum plasma spray(VPS) technology, and their corrosion behavior was studied via salt spray corrosion and electrochemical tests. Phase compositions and microstructures of these coatings before and after corrosion were characterized by X-ray diffraction(XRD) and scanning electron microscopy(SEM) facilitated with energy dispersive X-ray spectrometer(EDS). The results showed that spontaneous passivation of TAC-1 and TAC-2 granted the coatings excellent corrosion resistance than that of commercial Al/BN coating. Additionally, TAC-2 exhibited higher corrosion potential(Ecorr) and breakdown potential(Ebp) but a lower corrosion current density(icorr) than TAC-1. A small quantity of the corrosion product(Al(OH)3and Al O) could be detected on the surface of TAC-1, while no corrosion product appeared in TAC-2. The non-uniform elements distribution in the metal matrix of TAC-1 resulted in localized corrosion and relatively poor corrosion resistance compared to TAC-2.展开更多
文摘The accuracy(repeatability and reproducibility) of the iron content analysis of galvanized coating using an X-ray fluorescence spectrometer with an L-spectrum is not better than that of flame atomic absorption spectrometry, sometimes it exceeds the quality control limit.Influences, such as current, voltage, equipment(internal circulating water, 10%CH4+90%Ar, and vacuum) checking, instrument monitoring, sample cleaning, and oper-ators, were investigated by means of 6-sigma and lean operations to improve accuracy.
文摘The microstructure of hot-dip galvanized Zn-ll%A1-3%Mg-0.270Si alloy coating was studied in this article. X-ray diffraction analysis revealed the coating is composed by Zn, A1 and MgZn2 phase. Optical microscope (OM) and scanning electron microscope (SEM) observations showed the coating is occupied by snowflake-like dendrite, double hexagonal organization and eutectic. The coating backbone was the dendrite considered to be a phase of hexagonal close-packed (HCP) structure judging form its morphology according to the crystal growth way in the coating. Transmission electron microscopy (TEM) and energy dispersive spectroscopy (EDS) researches on the dendrite suggested that an intermediate Zn-A1 phase was formed at high temperature, then decomposed into a type of Zn-A1 granular eutectoid after cooling down to room temperature, while the eutectoid Zn and A1 had a certain crystallographic relationship. The coating solidification process and the grain crystal structure were discussed.
基金financially supported by the Fund of State Key Laboratory of Multiphase Complex Systems, IPE, CAS (No. MPCS-2012-A-06)the Natural Science Foundation of Jiangsu Province, China (No. BK2011452)
文摘Ti–Al mixed powder(Ti:Al = 3:1 in atomic ratio) and Ti3 Al intermetallic alloy powder mechanically clad hexagonal BN to fabricate Ti Al/BN and Ti3Al/BN composite powders. The corresponding porous abradable seal coatings(named as TAC-1 and TAC-2, respectively) were deposited using vacuum plasma spray(VPS) technology, and their corrosion behavior was studied via salt spray corrosion and electrochemical tests. Phase compositions and microstructures of these coatings before and after corrosion were characterized by X-ray diffraction(XRD) and scanning electron microscopy(SEM) facilitated with energy dispersive X-ray spectrometer(EDS). The results showed that spontaneous passivation of TAC-1 and TAC-2 granted the coatings excellent corrosion resistance than that of commercial Al/BN coating. Additionally, TAC-2 exhibited higher corrosion potential(Ecorr) and breakdown potential(Ebp) but a lower corrosion current density(icorr) than TAC-1. A small quantity of the corrosion product(Al(OH)3and Al O) could be detected on the surface of TAC-1, while no corrosion product appeared in TAC-2. The non-uniform elements distribution in the metal matrix of TAC-1 resulted in localized corrosion and relatively poor corrosion resistance compared to TAC-2.
