销售代表 Quantity of material handling equipmentA queuing theory based approach.docx

销售代表 Quantity of material handling equipmentA queuing theory based approach.docx

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销售代表QuantityofmaterialhandlingequipmentAqueuingtheorybasedapproach

销售代表

鸣乐（上海）贸易有限公司        查看公司简介>>

粉丝团（4）|

公司行业：

  贸易/进出口  批发/零售

公司性质：

  外资（欧美）

公司规模：

  少于50人

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发布日期：

2011-03-21

工作地点：

上海-卢湾区

招聘人数：

4

工作年限：

五年以上

语言要求：

英语 一般

学    历：

大专

薪水范围：

2000-2999

职位描述

本公司为具有悠久历史的德国家族企业在中国的子公司。

独家经销并代理欧洲著名品牌镜架。

根据业务需要，拟招聘四位销售代表。

年龄：

30－45岁。

有同领域经验者为优先考虑。

应聘者应能适应每月出差的工作特性。

有一定的英文水平。

身体健康，无不良嗜好。

应具备一定的销售才能，能吃苦耐劳，有独立的工作能力。

工作范围：

全国中、大城市

1、具有良好的沟通、协调能力和道德素质。

2、有敏锐的市场洞察力、灵活处理突发事件的能力；

3、有良好形象、性格开朗、乐观向上，思维敏捷，责任心强，注重工作效率；

4、为人正直、善于沟通，具有高度的敬业和团队合作精神；

5、具有较强的活动及组织能力，执行能力、有开拓进取和创新精神。

6、有良好的团队合作精神和敬业精神。

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粉丝团（4）|

MENRAD---鸣乐是一家拥有四代历史的德国家族企业。

如今销售及制造子公司已遍及德国、瑞士、奥地利、荷兰、英国及中国等全球各地。

延续四代的家族链以德国人的信守精神展示了MENRAD----鸣乐家族的百年轨迹。

本公司为其在中国的子公司。

独家经销并代理德国及欧洲著名品牌镜架。

根据业务需要，拟招聘两位销售代表。

年龄：

28－45岁。

有同领域经验者为优先考虑。

应聘者应能适应每月出差的工作特性。

有一定的英文水平。

身体健康，无不良嗜好。

应具备一定的销售才能，能吃苦耐劳，有独立的工作能力。

工作范围：

全国中、大城市

BuildinganExecutiveInformationSystemforMaintenanceEfficiencyinPetrochemicalPlants—AnEvaluation  OriginalResearchArticle

ProcessSafetyandEnvironmentalProtection,Volume85,Issue2,2007,Pages139-146

W.T.Hwang,S.W.Tien,C.M.Shu

 Closepreview  |  Relatedarticles  |  Relatedreferenceworkarticles    

AbstractAbstract|Figures/TablesFigures/Tables|ReferencesReferences

Abstract

Thisstudyusedthemanufacturingprocessinthepetrochemicalindustriesasanexampleanddevelopedadedicatedmaintenanceprogrammeandexecutiveinformationsystem（EIS）forthisindustry.ThesoftwareforEISwasestablishedonaCMMSplatform,withlogicalandextractiveanalysisusedtostoretheinformationinaKPIdatabank.Thesystemdevelopedcanprovideplantmanagersandengineerswithacompletesummaryofinformationandkeepthemupdatedregardingthepresentstatusoftheirmaintenanceefforts.Theobjectiveofthisstudywastoestablishamanagementsystemformaintainingknowledgeinthepetrochemicalindustries,suchasthemanagementofstandardoperatingprocedures（SOPs）,historicalrecordsandtheanalysisofdataforthefacility.Todesignthesoftware,areviewofpetrochemicalfacilitywaspurposedtoenhancethemaintenanceeffortsandfacilitatethedecision-makingprocess.Themainfunctionsofthesystemincludeassetreliabilityanalysis,failureanalysisandmaintenancebenefitcostanalysis.Forthepetrochemicalindustry,theimpactofsafetyandenvironmentcausedbyequipmentmalfunctionismoresubstantialthanthatofotherindustries.Ifexecutivescanmanageessentialpointseffectivelyandmakedecisionsaccordingtoakeyperformanceindex,riskstosafetyandenvironment,whichresultfromequipmentmalfunction,canbedecreasedandsafetycanbeenhancedforpetrochemicalrefineries.

ArticleOutline

Introduction

ResearchStructure

Definition

IndexEstablishmentandPreliminaryDesign

SystemDesign

IndexDesign

SystemDevelopment

Securityanduserprivilegesmanagement

Systemstructure

Systeminterface

DataRequirements

FunctionRequirements

Conclusions

References

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52

Datacenterdesignandlocation:

Consequencesforelectricityuseandgreenhouse-gasemissions  OriginalResearchArticle

BuildingandEnvironment,Volume46,Issue5,May2011,Pages990-998

ArmanShehabi,EricMasanet,HillaryPrice,ArpadHorvath,WilliamW.Nazaroff

 Closepreview  |  Supplementarycontent

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AbstractAbstract|Figures/TablesFigures/Tables|ReferencesReferences

Abstract

Therapidlyincreasingelectricitydemandfordatacenteroperationhasmotivatedeffortstobetterunderstandcurrentdatacenterenergyuseandtoidentifystrategiesthatreducetheenvironmentalimpactofthesebuildings.Thispaperbuildsonpreviousdatacenterenergymodelingeffortsbycharacterizinglocalclimateandmechanicalequipmentdifferencesamongdatacentersandthenevaluatingtheirconsequencesforbuildingenergyuse.CitiesintheUnitedStateswithsignificantdatacenteractivityareidentified.Representativeclimateconditionsforthesecitiesareappliedtodatacenterenergymodelsforseveraldifferentprototypicalspacetypes.Resultsindicatethatwidespread,effectiveeconomizeruseindatacenterscouldreduceenergydemandfordatacentersbyabout20–25%,equivalenttoanenergyefficiencyresourceintheUSof

13–17billionkWhperyear.Almosthalfofthepotentialsavingswouldresultfrombetterairflowmanagementandpropercontrolsequences.Thetotalenergysavingspotentialofeconomizers,althoughsubstantial,isconstrainedbytheirlimitedpotentialforuseinserverclosetsandserverrooms,whichtogetherareestimatedtoaccountforabout30%ofalldatacenterenergydemand.Incorporatingeconomizeruseintothemechanicalsystemsoflargerdatacenterswouldincreasethevariationinenergyefficiencyamonggeographicregions,indicatingthatasdatacenterbuildingsbecomemoreenergyefficient,theirlocationswillhaveanincreasingeffectonoverallenergydemand.Differencesamongregionsbecomeevenmoreimportantwhenaccountingforgreenhouse-gasemissions.Futuredatacenterdevelopmentcouldconsidersitelocation,alongwithefficiencymeasures,tolimittheenvironmentalimpactattributabletothisincreasinglyprominenteconomicsector.

ArticleOutline

1.Introduction

2.Methods

2.1.Serverclosets

2.2.Serverrooms

2.3.Localizeddatacenters

2.4.Mid-tierdatacenters

2.5.Enterprisedatacenters

2.6.Additionalnon-ITpowerloads

3.Resultsanddiscussion

4.Limitationsandfutureresearch

4.1.Characterizationofserverclosets

4.2.SpacetypedistributionofITenergy

4.3.Regionaldistributionofdatacenters

4.4.Greenhouse-gasemissionsfromdatacenters

5.Conclusion

Acknowledgements

Appendix.Supplementarymaterial

References

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53

StrategicplanningoncarboncapturefromcoalfiredplantsinMalaysiaandIndonesia:

Areview  OriginalResearchArticle

EnergyPolicy,Volume37,Issue5,May2009,Pages1718-1735

M.R.Othman,Martunus,R.Zakaria,W.J.N.Fernando

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AbstractAbstract|Figures/TablesFigures/Tables|ReferencesReferences

Abstract

MalaysiaandIndonesiabenefitinvariouswaysbyparticipatinginCDMandfrominvestmentsintheGHGemissionreductionprojects,interalia,technologytransfersuchascarboncapture（CC）technologyfortheexistingandfuturecoalfiredpowerplants.Amongthefossilfuelresourcesforenergygeneration,coalisofferinganattractivesolutiontotheincreasingfuelcost.TheconsumptionofcoalinMalaysiaandIndonesiaisgrowingatthefastestrateof9.7%and4.7%,respectively,peryearsince2002.ThetotalcoalconsumptionforelectricitygenerationinMalaysiaisprojectedtoincreasefrom12.4milliontonsin2005to36milliontonsin2020.InIndonesia,thecoalconsumptionforthesamecauseisprojectedtoincreasefrom29.4milliontonsin2005to75milliontonsin2020.CO2emissionfromcoalfiredpowerplantsareforecastedtogrowat4.1%peryear,reaching98milliontonsand171milliontonsinMalaysiaandIndonesia,respectively.

ArticleOutline

1.Introduction

1.1.Thecleandevelopmentmechanism

1.2.CanMalaysiaandIndonesiabenefitfromCDM?

1.3.Policies

1.3.1.Malaysiaenergypolicy

1.3.2.Indonesiaenergypolicy

1.3.3.Industrialisedcountriesenergypolicy

2.Carboncaptureandstorage

2.1.CO2capture

2.2.CoalplantandCC

2.2.1.CO2emissioninMalaysia

2.2.2.CO2emissioninIndonesia

3.ChoicesofcoalfiredpowerplantsforMalaysiaandIndonesia

3.1.Capturetechnologies

4.Conclusions

Acknowledgements

References

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54

Environmentalimpactassessmentofdifferentdesignschemesofanindustrialecosystem  OriginalResearchArticle

Resources,ConservationandRecycling,Volume51,Issue2,August2007,Pages294-313

AditiSingh,HelenH.Lou,CarlL.Yaws,JackR.Hopper,RalphW.Pike

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AbstractAbstract|Figures/TablesFigures/Tables|ReferencesReferences

Abstract

Industrialecosystemisanimportantapproachforsustainabledevelopment.Inanindustrialecosystem,agroupofindustriesareinter-connectedthroughmassandenergyexchangesformutualbenefits.However,somemassandenergyexchangeactivitiesmaycauseunexpectedenvironmentalimpacts.Therefore,itisvitaltoevaluatetheenvironmentalimpactsofthesymbiosisinordertoprovideaclearguidanceforthedecision-makersandstakeholders.

Theagro-chemicalcomplexintheLowerMississippiRiverCorridorwiththirteenchemicalandpetrochemicalindustriesemitshugeamountofcarbondioxide.Abi-leveldesignmethodologyisusedtoreconfigurethiscomplexforutilizingsurpluscarbondioxide.Byusingasuperstructure-basedapproach,anewdesignschemeforthisindustrialecosystemisproposed.Inthispaper,anLCA-typeenvironmentalimpactassessmentofdifferentdesignschemesforthiscomplexisconductedusingthesoftwareTRACI,atooldevelopedbytheUnitedStatesEnvironmentalProtectionAgency（USEPA）.Thisanalysiscomparesvariousenvironmentalimpactsofdifferentdesignsandidentifiesthepotentialtrade-offsindifferentenvironmentalimpactcategories.Thisinformationprovidesdeepinsightabouttheenvironmentalsustainabilityofindustrialecosystemsandfacilitatesthedevelopmentofthemosteco-effectivesymbiosisforrecycle,reuseandresourceconservation.

ArticleOutline

1.Introduction

2.Lifecyc