激光清洗的例子: 38xHSLoe.pdf_激光清洗的例子

<TABLE width="100%"><TR><TD vAlign=top width="8%">Authors: <TD width="92%">Drakaki, E; Karydas, AG; Klinkenberg, B; Kokkoris, M; Serafetinides, AA; Stavrou, E; Vlastou, R; Zarkadas, C <TR><TD vAlign=top width="8%">Title: <TD>Laser cleaning on Roman coins <TR><TD vAlign=top width="8%">Source: <TD><a href="http://ccc3.isiknowledge.com/CCC.cgi?SID=QSsHLQrg-GgAAD-jj0EPG=P1RQ=browse_tocb_selection=S_APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEdi=APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEb_sq=" target="_blank" >APPLIED PHYSICS A-MATERIALS SCIENCE PROCESSING, 79 (4-6): 1111-1115 SEP 2004</A> <TR><TD vAlign=top width="8%">KeyWords Plus: <TD vAlign=top>ARCHAEOMETRY; CORROSION; METALS; ART </TD></TR></TABLE>Abstract:
Ancient metal objects react with moisture and environmental chemicals to form various corrosion products. Because of the unique character and high value of such objects, any cleaning procedure should guarantee minimum destructiveness. The most common treatment used is mechanical stripping, in which it is difficult to avoid surface damage when employed. Lasers are currently being tested for a wide range of conservation applications. Since they are highly controllable and can be selectively applied, lasers can be used to achieve more effective and safer cleaning of archaeological artifacts and protect their surface details. The basic criterion that motivated us to use lasers to clean Roman coins was the requirement of pulsed emission, in order to minimize heat-induced damages. In fact, the laser interaction with the coins has to be short enough, to produce a fast removal of the encrustation, avoiding heat conduction into the substrate. The cleaning effects of three lasers operating at different wavelengths, namely a TEA CO2 laser emitting at 10.6 mum, an Er:YAG laser at 2.94 mum, and a 2omega-Nd:YAG laser at 532 nm have been compared on corroded Romans coins and various atomic and nuclear techniques have also been applied to evaluate the efficiency of the applied procedure.
<TABLE width="100%"><TR><TD vAlign=top width="8%">Reprints: <TD>DRAKAKI E,NATL TECH UNIV ATHENS,DEPT PHYS;ZOGRAFOU CAMPUS; ATHENS 15780, GREECE.
<a href="mailtedrakaki@central.ntua.gr" target="_blank" >edrakaki@central.ntua.gr</A> <TR><TD vAlign=top width="8%">Research
Institutions: <TD>Natl Tech Univ Athens, Dept Phys, Athens 15780, Greece.
NCSR Demokritos, Inst Nucl Phys, Tandem Accelerator Lab, Lab Mat Anal, GR-15310 Athens, Greece. <TR><TD vAlign=top width="8%">Discipline: <TD>APPLIED PHYSICS/CONDENSED MATTER/MATERIALS SCIENCE <a href="http://ccc3.isiknowledge.com/CCC.cgi?SID=QSsHLQrg-GgAAD-jj0EPG=P1RQ=wcsummaryDI=APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEED=S" target="_blank" ><img src="http://ccc3.isiknowledge.com/images/cwclink2.gif"></A>
SEMICONDUCTORS SOLID STATE MATERIALS TECHNOLOGY
<TR><TD vAlign=top width="8%">CC Editions / Collections: <TD>

hysical, Chemical Earth Sciences (PCES);
Electronics Telecommunications Collection (EC) <TR><TD vAlign=top width="8%">Language: <TD>English <TR><TD vAlign=top width="8%">Document type: <TD>Article <TR><TD vAlign=top width="8%">IDS No.: <TD>839EL <TR><TD vAlign=top width="8%">

ublisher: <TD>SPRINGER, 233 SPRING STREET, NEW YORK, NY 10013 USA, <a href="http://www.springer-ny.com/" target="_blank" >http://www.springer-ny.com</A> </TD></TR></TABLE>

<TABLE width="100%"><TR><TD vAlign=top width="8%">Authors: <TD width="92%">Drakaki, E; Karydas, AG; Klinkenberg, B; Kokkoris, M; Serafetinides, AA; Stavrou, E; Vlastou, R; Zarkadas, C <TR><TD vAlign=top width="8%">Title: <TD>Laser cleaning on Roman coins <TR><TD vAlign=top width="8%">Source: <TD><a href="http://ccc3.isiknowledge.com/CCC.cgi?SID=QSsHLQrg-GgAAD-jj0EPG=P1RQ=browse_tocb_selection=S_APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEdi=APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEb_sq=" target="_blank" >APPLIED PHYSICS A-MATERIALS SCIENCE PROCESSING, 79 (4-6): 1111-1115 SEP 2004</A> <TR><TD vAlign=top width="8%">KeyWords Plus: <TD vAlign=top>ARCHAEOMETRY; CORROSION; METALS; ART </TD></TR></TABLE>Abstract:
Ancient metal objects react with moisture and environmental chemicals to form various corrosion products. Because of the unique character and high value of such objects, any cleaning procedure should guarantee minimum destructiveness. The most common treatment used is mechanical stripping, in which it is difficult to avoid surface damage when employed. Lasers are currently being tested for a wide range of conservation applications. Since they are highly controllable and can be selectively applied, lasers can be used to achieve more effective and safer cleaning of archaeological artifacts and protect their surface details. The basic criterion that motivated us to use lasers to clean Roman coins was the requirement of pulsed emission, in order to minimize heat-induced damages. In fact, the laser interaction with the coins has to be short enough, to produce a fast removal of the encrustation, avoiding heat conduction into the substrate. The cleaning effects of three lasers operating at different wavelengths, namely a TEA CO2 laser emitting at 10.6 mum, an Er:YAG laser at 2.94 mum, and a 2omega-Nd:YAG laser at 532 nm have been compared on corroded Romans coins and various atomic and nuclear techniques have also been applied to evaluate the efficiency of the applied procedure.
<TABLE width="100%"><TR><TD vAlign=top width="8%">Reprints: <TD>DRAKAKI E,NATL TECH UNIV ATHENS,DEPT PHYS;ZOGRAFOU CAMPUS; ATHENS 15780, GREECE.
<a href="mailtedrakaki@central.ntua.gr" target="_blank" >edrakaki@central.ntua.gr</A> <TR><TD vAlign=top width="8%">Research
Institutions: <TD>Natl Tech Univ Athens, Dept Phys, Athens 15780, Greece.
NCSR Demokritos, Inst Nucl Phys, Tandem Accelerator Lab, Lab Mat Anal, GR-15310 Athens, Greece. <TR><TD vAlign=top width="8%">Discipline: <TD>APPLIED PHYSICS/CONDENSED MATTER/MATERIALS SCIENCE <a href="http://ccc3.isiknowledge.com/CCC.cgi?SID=QSsHLQrg-GgAAD-jj0EPG=P1RQ=wcsummaryDI=APPLIED+PHYSICS/CONDENSED+MATTER/MATERIALS+SCIENCEED=S" target="_blank" ><img src="http://ccc3.isiknowledge.com/images/cwclink2.gif"></A>
SEMICONDUCTORS SOLID STATE MATERIALS TECHNOLOGY
<TR><TD vAlign=top width="8%">CC Editions / Collections: <TD>

hysical, Chemical Earth Sciences (PCES);
Electronics Telecommunications Collection (EC) <TR><TD vAlign=top width="8%">Language: <TD>English <TR><TD vAlign=top width="8%">Document type: <TD>Article <TR><TD vAlign=top width="8%">IDS No.: <TD>839EL <TR><TD vAlign=top width="8%">

ublisher: <TD>SPRINGER, 233 SPRING STREET, NEW YORK, NY 10013 USA, <a href="http://www.springer-ny.com/" target="_blank" >http://www.springer-ny.com</A> </TD></TR></TABLE>

我公司曾用TEA CO2激光器在国内一家规模较大的轮胎厂清洗轮胎模具,效果非常好,国外也有这方面的报道,这种激光器脉宽窄(几微秒),峰值功率高(兆瓦级),非常适合清洗.与国外相比我们的脉冲频率及自动化程度还需较大改进.

<

>图片上好象有给鸽子洗羽毛的,对人体没有伤害吗?功率多大<

>以前没听说过这玩意,谁给偶介绍一下啊 <

>ps:买一台回来就不用洗澡了~~ :)

<

>好像不错哦<

>不过不知道是什么波长的<

>用什么类型的激光器

我怎么打不开啊，上面的兄弟，我对你这个很感兴趣，能联系一下吗？qq:3359504 13077894386

<

>用的是Nd:YAG1064nm的纳秒激光器

<

>我们做过给工艺品的清洗，使用1064或532nm的Nd:YAG激光，ns级，效果不错。<

>国外经常有用这个来除去名画家油画上面覆盖的不出名画家的一般油画，这样有钱赚的哦。

资料分类导航

热门下载

激光清洗的例子: 38xHSLoe.pdf


热搜: 防雾膜棒料红外反射膜光电二极管镀膜机反射膜光谱仪光电探头真空镀银滤光片光器件应用光学 zemax激光远心镜头 sio2 增透膜离子源栅网 zemax 论文高反膜半反半透膜