数字赋能让建筑工地“耳聪目明” 济南5个三星级智慧工地施工企业

在诸神黄昏时，数字施工芬尼尔终于挣脱束缚，并在战场上吞噬了奥丁，但也被随后赶来的森林之神维达杀死。

让建该成果以题为Cellulose-BasedFlexibleFunctionalMaterialsforEmergingIntelligentElectronics发表在了Adv.Mater.上。筑工智慧i）透明纤维素纸的光散射效果数码照片。

i）PSC自供电系统的充/放电曲线，耳聪及由自供电系统支持工作的温湿传感器。目明图7 纤维素材料在柔性有机薄膜晶体管（OTFT）中的应用a）纤维素纳米纸基OTFT阵列的制造工艺示意图。引入氨基酸、个工地蛋白质、DNA等结构基序，研发性能可设计性纤维素离子凝胶与生物材料，扩展其在生物电子器件领域的应用前景。

d）该设备在圆筒上滚动的数码照片，星级显示其柔性。相关参考文献[1]陈文帅,于海鹏,刘一星,蒋乃翔,陈鹏.木质纤维素纳米纤丝制备及形态特征分析.高分子学报,2010,41(11):1320-1326.[2]WenshuaiChen,HaipengYu,YixingLiu,PengChen.Individualizationofcellulosenanofibersfromwoodusinghigh-intensityultrasonicationcombinedwithchemicalpretreatments.CarbohydratePolymers,2011,83(4):1804-1811.[3]YannaLi,YongzhuangLiu,WenshuaiChen,QingwenWang,YixingLiu,JianLi,HaipengYu.Facileextractionofcellulosenanocrystalsfromwoodusingethanolandperoxidesolvothermalpretreatmentfollowedbyultrasonicnanofibrillation.GreenChemistry,2016,18(4):1010-1018.[4]YongzhuangLiu,WenshuaiChen,QinqinXia,BingtuoGuo,QingwenWang,ShouxinLiu,YixingLiu,JianLi,HaipengYu.Efficientcleavageoflignin-carbohydratecomplexesandultrafastextractionofligninoligomersfromwoodbiomassbymicrowave-assistedtreatmentwithdeepeutecticsolvent.ChemSusChem,2017,10(8):1692-1700.[5]YueMa,QinqinXia,YongzhuangLiu,WenshuaiChen,ShouxinLiu,QingwenWang,YixingLiu,JianLi,HaipengYu.Productionofnanocelluloseusinghydrateddeepeutecticsolventcombinedwithultrasonictreatment.ACSOmega,DOI:10.1021/acsomega.9b05198.[6]WenshuaiChen,HaipengYu,YixingLiu,YunfeiHai,MingxinZhang,PengChen.Isolationandcharacterizationofcellulosenanofibersfromfourplantcellulosefibersusingchemical-ultrasonicprocess.Cellulose,2011,18(2):433-442.[7]YongzhuangLiu,BingtuoGuo,QinqinXia,JuanMeng,WenshuaiChen,ShouxinLiu,QingwenWang,YixingLiu,JianLi,HaipengYu.Efficientcleavageofstronghydrogenbondsincottonbyacidicdeepeutecticsolventsandfabricationofcellulosenanocrystalswithhighyields.ACSSustainableChemistryEngineering,2017,5(9):7623-7631.[8]陈文帅,于海鹏,李勍,刘一星,李坚.纳米纤维素—机械法制备与应用基础.北京:科学出版社,2014.[9]PengChen,HaipengYu,YixingLiu,WenshuaiChen,XiaoqingWang,MiOuyang.Concentrationeffectsontheisolationanddynamicrheologicalbehaviorofcellulosenanofibersviaultrasonicprocessing.Cellulose,2013,20(1):149-157.[10]WenshuaiChen,HaipengYu,YixingLiu.Preparationofmillimeter-longcelluloseInanofiberswithdiametersof30–80nmfrombamboofibers.CarbohydratePolymers,2011,86(2):453-461.[11]WenshuaiChen,QingLi,YouchengWang,XinYi,JieZeng,HaipengYu,YixingLiu,JianLi.Comparativestudyofaerogelsobtainedfromdifferentlypreparednanocellulosefibers.ChemSusChem,2014,7(1):154-161.[12]QingLi,WenshuaiChen,YannaLi,XiaoyuGuo,ShanSong,YixingLiu,JianLi,HaipengYu,JieZeng.Comparativestudyofthestructure,mechanicalandthermomechanicalpropertiesofcellulosenanopaperswithdifferentthickness.Cellulose,2016,23(2):1375-1382.[13]YaoTan,YongzhuangLiu,WenshuaiChen,YixingLiu,QingwenWang,JianLi,HaipengYu.Homogeneousdispersionofcellulosenanofibersinwaterborneacryliccoatingswithimprovedpropertiesandunreducedtransparency.ACSSustainableChemistryEngineering,2016,4(7):3766-3772.[14]JialiGao,QingLi,WenshuaiChen,YixingLiu,HaipengYu.Self-assemblyofnanocelluloseandindomethacinintohierarchicallyorderedstructureswithhighencapsulationefficiencyforsustainedreleaseapplications.ChemPlusChem,2014,79(5):725-731.[15]TianhongLu,QingLi,WenshuaiChen,HaipengYu.Compositeaerogelsbasedondialdehydenanocelluloseandcollagenforpotentialapplicationsaswounddressingandtissueengineeringscaffold.CompositesScienceandTechnology,2014,94:132-138.[16]LuSun,WenshuaiChen,YixingLiu,JianLi,HaipengYu.Soyproteinisolate/cellulosenanofibercomplexgelsasfatsubstitutes:Rheologicalandtexturalpropertiesandextentofcreamimitation.Cellulose,2015,22(4):2619-2627.[17]XiaoheLi,YongzhuangLiu,YanyanYu,WenshuaiChen,YixingLiu,HaipengYu.Nanoformulationsofquercetinandcellulosenanofibersashealthcaresupplementswithsustainedantioxidantactivity.CarbohydratePolymers,2019,207:160-168.[18]WenshuaiChen,QiZhang,KojiroUetani,QingLi,PingLu,JunCao,QingwenWang,YixingLiu,JianLi,ZhichaoQuan,YongshiZhang,SifanWang,ZhenyuMeng,HaipengYu.Sustainablecarbonaerogelsderivedfromnanofibrillatedcelluloseashigh-performanceabsorptionmaterials.AdvancedMaterialsInterfaces,2016,3:1600004.[19]YushuWang,JialiangWang,ShengjieLing,HaiweiLiang,MingDai,LuluBai,QingLi, ZhuangjunFan,Sang-YoungLee,HaipengYu,ShouxinLiu,QingwenWang,YixingLiu, JianLi,TianmengSun,WenshuaiChen.Wood-derivednanofibrillatedcellulosehydrogelfilters forfastandefficientseparationofnanoparticles.Advanced SustainableSystems, 2019,3(9): 1900063[20]QiZhang,ChaojiChen,WenshuaiChen,GlennPastel,XiaoyuGuo,ShouxinLiu, QingwenWang,YixingLiu, JianLi,HaipengYu,LiangbingHu.Nanocellulose-enabled,all-nanofiber,high-performancesupercapacitor.ACSAppliedMaterialsInterfaces,2019,11(6): 5919-5927[21]WenshuaiChen,HaipengYu,Sang-YoungLee,TongWei,JianLi,ZhuangjunFan.Nanocellulose:apromisingnanomaterialforadvancedelectrochemicalenergystorage.ChemicalSocietyReviews,2018,47:2837-2872.本文由木文韬翻译，企业材料牛整理编辑。

数字施工e）柔性RFID金属天线的电导率与折叠角比值。

让建图10 纤维素材料在微型医疗设备中的应用a）银@金纳米颗粒/纤维素纸的合成示意图及其在水体毒素检测中的应用。此外，筑工智慧MicroLED的体积约为目前主流LED大小的1%，筑工智慧且应用范围非常广阔，可应用小至手环和手表等可穿戴设备，大至商用广告牌和公共显示屏，甚至VR或者VR设备等的，并且表现比传统的液晶面板甚至OLED都更好一些。

相比OLED，耳聪MicroLED的亮度也要更高一些，而且寿命也会更长，性能更加稳定，亮度和色彩饱和度更高，响应速度也更快消息称LG2024款OLED电视处理器也将大升级，目明型号为Alpha10，目明新款芯片的NPU性能将会显著加强，具备改进的图像分析、降噪、物体识别功能以及基于人工智能的音频增强功能。

外媒认为，个工地G4系列将采用亮度更高且拥有更好抗反射涂层的MLAOLED面板，C4系列则不会采用该面板。11月26日消息，星级据flatpanelshd消息，LG新款C4/G4OLED电视的首张照片已在韩国safetykorea认证数据库中出现。