This document contains the proceedings from the Fourth International Symposium on Recycling of Metals and Engineered Materials held in 2000. It includes 58 papers presented at the symposium organized by the Recycling Committee of the Extraction & Processing Division and the Light Metals Division of The Minerals, Metals & Materials Society (TMS). The symposium covered topics related to recycling metals, including secondary lead, EAF dust processing, secondary copper/nickel/cobalt, consumer battery recycling, and more. It provides a forum for discussing both fundamental and practical aspects of recycling various materials.
DUG Bakken and Niobrara 2015 Conference Previewbdeese
DUG Bakken and Niobrara conference and exhibition will discuss topics focused on creating profit through efficiency while reducing cost and adding takeaway.
While the world seeks a new equilibrium for tumbling oil prices, producers throughout the Rockies are laser focused on cutting costs by operating more efficiently. Everything from optimized completion strategies and streamlined logistics, to new frac spacing methods and fuel substitution is being tested.
The resilience of North America's shale revolution is being tested, but the very innovative spirit that started it all is keeping producers ahead.
DUG Bakken and Niobrara 2015 will unite more than 2,500 oil and gas professionals, 25+ executive-level speakers and 200+ exhibitors in Denver for two days of candid discussions on how producers are cutting costs by operating more efficiently. Click here to learn more about why you can't afford to miss the region's #1 unconventional resources event.
Nanofibers contolling heavy metal contamination reportMr. Lucky
Plenty of fresh water resources are still inaccessible for human use. Calamities such as pollution, climate change, and global warming pose serious threats to the fresh water system. Although many naturally and synthetically grown materials have been taken up to resolve these issues, there is still plenty of room for enhancements in technology and material perspectives to maximize resources and to minimize harm. Considering the challenges related to the purification of water, materials in the form of nanofiber membranes and nanomaterials have made tremendous contributions to water purification. Nanofiber membranes made of synthetic polymer nanofibers, ceramic membranes etc., metal oxides in various morphologies, and carbonaceous materials were explored in relation to waste removal from water. Membranes for membrane adsorption (MA) have the dual function of membrane filtration and adsorption to be very effective to remove trace amounts of pollutants such as cationic heavy metals, anionic phosphates and nitrates. In addition, recent progresses in the development of advanced adsorbents such as nanoparticles are summarized, since they are potentially useful as fillers in the host membrane to enhance its performance.
DUG Bakken and Niobrara 2015 Conference Previewbdeese
DUG Bakken and Niobrara conference and exhibition will discuss topics focused on creating profit through efficiency while reducing cost and adding takeaway.
While the world seeks a new equilibrium for tumbling oil prices, producers throughout the Rockies are laser focused on cutting costs by operating more efficiently. Everything from optimized completion strategies and streamlined logistics, to new frac spacing methods and fuel substitution is being tested.
The resilience of North America's shale revolution is being tested, but the very innovative spirit that started it all is keeping producers ahead.
DUG Bakken and Niobrara 2015 will unite more than 2,500 oil and gas professionals, 25+ executive-level speakers and 200+ exhibitors in Denver for two days of candid discussions on how producers are cutting costs by operating more efficiently. Click here to learn more about why you can't afford to miss the region's #1 unconventional resources event.
Nanofibers contolling heavy metal contamination reportMr. Lucky
Plenty of fresh water resources are still inaccessible for human use. Calamities such as pollution, climate change, and global warming pose serious threats to the fresh water system. Although many naturally and synthetically grown materials have been taken up to resolve these issues, there is still plenty of room for enhancements in technology and material perspectives to maximize resources and to minimize harm. Considering the challenges related to the purification of water, materials in the form of nanofiber membranes and nanomaterials have made tremendous contributions to water purification. Nanofiber membranes made of synthetic polymer nanofibers, ceramic membranes etc., metal oxides in various morphologies, and carbonaceous materials were explored in relation to waste removal from water. Membranes for membrane adsorption (MA) have the dual function of membrane filtration and adsorption to be very effective to remove trace amounts of pollutants such as cationic heavy metals, anionic phosphates and nitrates. In addition, recent progresses in the development of advanced adsorbents such as nanoparticles are summarized, since they are potentially useful as fillers in the host membrane to enhance its performance.
Busbars are used within electrical installations for distributing power from a supply point to a number of output circuits. They may be used in a variety of configurations ranging from vertical risers – carrying current to each floor of a multi-storey building – to bars used entirely within a distribution panel or within an industrial process.
This publication describes the main issues that need to be addressed in the design of busbar systems, such as temperature rise due to energy losses; energy efficiency and lifetime cost; short-circuit current stresses and protection; jointing methods and performance; and maintenance.
Copper Development Association first published the popular Copper Busbars: Guidance for Design and Installation in 1936. The current edition adds significant content on busbar profiles and simplified formulae for busbar configurations. It is of particular benefit to design engineers of electrical distribution systems seeking to design efficient, economic and reliable busbar systems.
"Copper Busbars" is divided into six chapters. The introductory chapter focuses on materials for busbars, detailing the properties of a conductor material that are essential to achieve a long and reliable service life at the lowest lifetime cost. It reviews conductor materials for busbars and concludes that the required combination of properties is a very good match for copper.
The book includes a completely-revised chapter on current-carrying capacity. Original work performed for the book allowed to greatly simplify the calculation of current-carrying capacity of busbars by providing exact formulae for some common busbar configurations, and graphical methods for others. This should be of great help to designers in calculating ratings for their busbar systems.
The book also features a brand new chapter on profiles. This content was added because busbar profiles are seeing increasingly use in distribution panels and switchboards, but the design considerations for this application are significantly different from long vertical and horizontal busbars. It is a growing market since busbar profiles offer distinct advantages, such as material savings, lower assembly time, lower complexity and reduced scrap.
Other chapters cover lifecycle costing, short-circuit effects and jointing techniques for busbars. An annex provides valuable information on busbar coatings, focusing on the reasons for coating them, methods of coating, inspection and maintenance.
Since 1936, the Copper Network publishes 'Copper in Busbars'. The newest edition is currently available in 6 chapters and one annex:
1. Introduction
2. Current Carrying Capacity
3. Life Cycle Costing
4. Short-Circuit Effects
5. Profiles
6. Jointing
Annex on coating
APPENDICES California Energy Commission 500-2013-134-APPENDIXESFranco Moriconi
APPENDIX A: Zenergy Power HTS FCL Test Plan APPENDIX B: Zenergy Power HTS FCL Laboratory Test APPENDIX C: Zenergy Power HTS FCL Dielectric and HV Tests
APPENDIX D: Zenergy Power HTS FCL Normal State Temperature Rise Test
APPENDIX E: Zenergy Power HTS FCL Short Circuit Test APPENDIX F: Zenergy Power HTS FCL High Voltage Field Test
APPENDIX G: Zenergy Power HTS FCL Operation Manual APPENDIX H: Zenergy Power HTS FCL Cryostat Evacuation and Moisture Removal Procedure
APPENDIX I: Zenergy Power HTS FCL Liquid Nitrogen Fill Procedure
Part of the future of recycling will be innovative efforts to use the recycled materials. The trash-throw-away society has to make the transition from the Age of Growth into the Age of Survival before that happens to any great extent. The younger generations will lead the way once they realize the past cannot be revived.
Recycling electrical wire may not be a multi-million dollar market in the future, but it will be a living!
Saville Discovers High-Grade Niobium-Tantalum Boulders, And Possibly The Sour...Stephan Bogner
Today, Saville Resources Inc. reported lab results from its inaugural exploration program at its Niobium Claim Group Property in Québec. Most importantly for the upcoming drill program, the source of these strongly mineralized boulders appears to be found now.
The results speak for themselves and show the vast potential to make a major discovery with the upcoming drilling program:
• “A total for 14 rock samples with assays >0.80% Nb2O5, to a peak of 1.50% Nb2O5. Strong tantalum associated with best overall sample assaying 0.88% Nb2O5 and 1,080 ppm Ta2O5
• Discovery of new target area with boulder assays of 1.28% Nb2O5 and 0.88% Nb2O5
• Detailed ground magnetic survey completed over the Miranna and Southeast area targets
• Multiple target areas now drill ready“
To put this into perspective: Most of the current exploration, development and operating niobium mines have resource grades with a minimum of 0.3% Nb2O5.
A Novel Technology for Fracking Wastewater TreatmentGwen Jordaan
MGP Biotechnologies is a company focused on developing a water remediation technology that selectively removes heavy metal from water. We are currently exploring applications of the technology to the fracking industry. In particular, we believe our technology can be used to remove heavy metal from the flowback water. Our technology is a highly efficient, cost effective and sustainable approach to solving the problem of toxic heavy metal contamination.
Busbars are used within electrical installations for distributing power from a supply point to a number of output circuits. They may be used in a variety of configurations ranging from vertical risers – carrying current to each floor of a multi-storey building – to bars used entirely within a distribution panel or within an industrial process.
This publication describes the main issues that need to be addressed in the design of busbar systems, such as temperature rise due to energy losses; energy efficiency and lifetime cost; short-circuit current stresses and protection; jointing methods and performance; and maintenance.
Copper Development Association first published the popular Copper Busbars: Guidance for Design and Installation in 1936. The current edition adds significant content on busbar profiles and simplified formulae for busbar configurations. It is of particular benefit to design engineers of electrical distribution systems seeking to design efficient, economic and reliable busbar systems.
"Copper Busbars" is divided into six chapters. The introductory chapter focuses on materials for busbars, detailing the properties of a conductor material that are essential to achieve a long and reliable service life at the lowest lifetime cost. It reviews conductor materials for busbars and concludes that the required combination of properties is a very good match for copper.
The book includes a completely-revised chapter on current-carrying capacity. Original work performed for the book allowed to greatly simplify the calculation of current-carrying capacity of busbars by providing exact formulae for some common busbar configurations, and graphical methods for others. This should be of great help to designers in calculating ratings for their busbar systems.
The book also features a brand new chapter on profiles. This content was added because busbar profiles are seeing increasingly use in distribution panels and switchboards, but the design considerations for this application are significantly different from long vertical and horizontal busbars. It is a growing market since busbar profiles offer distinct advantages, such as material savings, lower assembly time, lower complexity and reduced scrap.
Other chapters cover lifecycle costing, short-circuit effects and jointing techniques for busbars. An annex provides valuable information on busbar coatings, focusing on the reasons for coating them, methods of coating, inspection and maintenance.
Since 1936, the Copper Network publishes 'Copper in Busbars'. The newest edition is currently available in 6 chapters and one annex:
1. Introduction
2. Current Carrying Capacity
3. Life Cycle Costing
4. Short-Circuit Effects
5. Profiles
6. Jointing
Annex on coating
APPENDICES California Energy Commission 500-2013-134-APPENDIXESFranco Moriconi
APPENDIX A: Zenergy Power HTS FCL Test Plan APPENDIX B: Zenergy Power HTS FCL Laboratory Test APPENDIX C: Zenergy Power HTS FCL Dielectric and HV Tests
APPENDIX D: Zenergy Power HTS FCL Normal State Temperature Rise Test
APPENDIX E: Zenergy Power HTS FCL Short Circuit Test APPENDIX F: Zenergy Power HTS FCL High Voltage Field Test
APPENDIX G: Zenergy Power HTS FCL Operation Manual APPENDIX H: Zenergy Power HTS FCL Cryostat Evacuation and Moisture Removal Procedure
APPENDIX I: Zenergy Power HTS FCL Liquid Nitrogen Fill Procedure
Part of the future of recycling will be innovative efforts to use the recycled materials. The trash-throw-away society has to make the transition from the Age of Growth into the Age of Survival before that happens to any great extent. The younger generations will lead the way once they realize the past cannot be revived.
Recycling electrical wire may not be a multi-million dollar market in the future, but it will be a living!
Saville Discovers High-Grade Niobium-Tantalum Boulders, And Possibly The Sour...Stephan Bogner
Today, Saville Resources Inc. reported lab results from its inaugural exploration program at its Niobium Claim Group Property in Québec. Most importantly for the upcoming drill program, the source of these strongly mineralized boulders appears to be found now.
The results speak for themselves and show the vast potential to make a major discovery with the upcoming drilling program:
• “A total for 14 rock samples with assays >0.80% Nb2O5, to a peak of 1.50% Nb2O5. Strong tantalum associated with best overall sample assaying 0.88% Nb2O5 and 1,080 ppm Ta2O5
• Discovery of new target area with boulder assays of 1.28% Nb2O5 and 0.88% Nb2O5
• Detailed ground magnetic survey completed over the Miranna and Southeast area targets
• Multiple target areas now drill ready“
To put this into perspective: Most of the current exploration, development and operating niobium mines have resource grades with a minimum of 0.3% Nb2O5.
A Novel Technology for Fracking Wastewater TreatmentGwen Jordaan
MGP Biotechnologies is a company focused on developing a water remediation technology that selectively removes heavy metal from water. We are currently exploring applications of the technology to the fracking industry. In particular, we believe our technology can be used to remove heavy metal from the flowback water. Our technology is a highly efficient, cost effective and sustainable approach to solving the problem of toxic heavy metal contamination.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)MdTanvirMahtab2
This presentation is about the working procedure of Shahjalal Fertilizer Company Limited (SFCL). A Govt. owned Company of Bangladesh Chemical Industries Corporation under Ministry of Industries.
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
6th International Conference on Machine Learning & Applications (CMLA 2024) will provide an excellent international forum for sharing knowledge and results in theory, methodology and applications of on Machine Learning & Applications.
HEAP SORT ILLUSTRATED WITH HEAPIFY, BUILD HEAP FOR DYNAMIC ARRAYS.
Heap sort is a comparison-based sorting technique based on Binary Heap data structure. It is similar to the selection sort where we first find the minimum element and place the minimum element at the beginning. Repeat the same process for the remaining elements.
NUMERICAL SIMULATIONS OF HEAT AND MASS TRANSFER IN CONDENSING HEAT EXCHANGERS...ssuser7dcef0
Power plants release a large amount of water vapor into the
atmosphere through the stack. The flue gas can be a potential
source for obtaining much needed cooling water for a power
plant. If a power plant could recover and reuse a portion of this
moisture, it could reduce its total cooling water intake
requirement. One of the most practical way to recover water
from flue gas is to use a condensing heat exchanger. The power
plant could also recover latent heat due to condensation as well
as sensible heat due to lowering the flue gas exit temperature.
Additionally, harmful acids released from the stack can be
reduced in a condensing heat exchanger by acid condensation. reduced in a condensing heat exchanger by acid condensation.
Condensation of vapors in flue gas is a complicated
phenomenon since heat and mass transfer of water vapor and
various acids simultaneously occur in the presence of noncondensable
gases such as nitrogen and oxygen. Design of a
condenser depends on the knowledge and understanding of the
heat and mass transfer processes. A computer program for
numerical simulations of water (H2O) and sulfuric acid (H2SO4)
condensation in a flue gas condensing heat exchanger was
developed using MATLAB. Governing equations based on
mass and energy balances for the system were derived to
predict variables such as flue gas exit temperature, cooling
water outlet temperature, mole fraction and condensation rates
of water and sulfuric acid vapors. The equations were solved
using an iterative solution technique with calculations of heat
and mass transfer coefficients and physical properties.
Water billing management system project report.pdfKamal Acharya
Our project entitled “Water Billing Management System” aims is to generate Water bill with all the charges and penalty. Manual system that is employed is extremely laborious and quite inadequate. It only makes the process more difficult and hard.
The aim of our project is to develop a system that is meant to partially computerize the work performed in the Water Board like generating monthly Water bill, record of consuming unit of water, store record of the customer and previous unpaid record.
We used HTML/PHP as front end and MYSQL as back end for developing our project. HTML is primarily a visual design environment. We can create a android application by designing the form and that make up the user interface. Adding android application code to the form and the objects such as buttons and text boxes on them and adding any required support code in additional modular.
MySQL is free open source database that facilitates the effective management of the databases by connecting them to the software. It is a stable ,reliable and the powerful solution with the advanced features and advantages which are as follows: Data Security.MySQL is free open source database that facilitates the effective management of the databases by connecting them to the software.
Sachpazis:Terzaghi Bearing Capacity Estimation in simple terms with Calculati...Dr.Costas Sachpazis
Terzaghi's soil bearing capacity theory, developed by Karl Terzaghi, is a fundamental principle in geotechnical engineering used to determine the bearing capacity of shallow foundations. This theory provides a method to calculate the ultimate bearing capacity of soil, which is the maximum load per unit area that the soil can support without undergoing shear failure. The Calculation HTML Code included.
Welcome to WIPAC Monthly the magazine brought to you by the LinkedIn Group Water Industry Process Automation & Control.
In this month's edition, along with this month's industry news to celebrate the 13 years since the group was created we have articles including
A case study of the used of Advanced Process Control at the Wastewater Treatment works at Lleida in Spain
A look back on an article on smart wastewater networks in order to see how the industry has measured up in the interim around the adoption of Digital Transformation in the Water Industry.
NO1 Uk best vashikaran specialist in delhi vashikaran baba near me online vas...Amil Baba Dawood bangali
Contact with Dawood Bhai Just call on +92322-6382012 and we'll help you. We'll solve all your problems within 12 to 24 hours and with 101% guarantee and with astrology systematic. If you want to take any personal or professional advice then also you can call us on +92322-6382012 , ONLINE LOVE PROBLEM & Other all types of Daily Life Problem's.Then CALL or WHATSAPP us on +92322-6382012 and Get all these problems solutions here by Amil Baba DAWOOD BANGALI
#vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore#blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #blackmagicforlove #blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #Amilbabainuk #amilbabainspain #amilbabaindubai #Amilbabainnorway #amilbabainkrachi #amilbabainlahore #amilbabaingujranwalan #amilbabainislamabad
We have compiled the most important slides from each speaker's presentation. This year’s compilation, available for free, captures the key insights and contributions shared during the DfMAy 2024 conference.
2. Fourth International
Symposium on
RECYCLING OF
METALSAND
ENGINEERED
MATERIALS
Proceedingsof a Symposiumorganized by the Recycling
Committeeof the Extraction & ProcessingDivision and
the Light Metals Division of TMS
October 22-25,2000
Edited by
Donald L. Stewart,Jr.
Alcoa Inc.
Alcoa Center, Pennsylvania
James C. Daley
Daley h Associates
Phoenix, Arizona
Robert L. Stephens
ComincoResearch
Trail, B,C., Canada
A Publication of
TMS
3. A Publication of The Minerals, Metals & Materials Society
184ThornHill Road
Warrendale, Pennsylvania15086-7528
(724)776-9000
Visit the TMSweb site at
http:// www.trnS.org
I
TheMinerals,Metals& Materialssocietyisnot
responsiblefor statementsor opinionsand isabsolved
of liability due to misuse of informationcontainedin
thispublication.
I
Printedin the United Statesof America
Library of CongressCatalogNumber 00-107604
ISBN Number 0-87339-4941
Authorizationtophotocopyitems
forinternal or personaluse, or the
internalorpersonaluse of specific
clients,isgrantedbyTheMinerals,
Metals& Materialssocietyfor us-
ers registered with the Copyright
ClearanceCenter (CCC)Transac-
tionalReportingService,provided
that thebasefee of $3.00per copy
ispaiddirectlytoCopyrightClear-
ance Center, 27 Congress Street,
Salem, Massachusetts 01970.For
thoseorganizationsthathavebeen
granted a photocopy license by
Copyright Clearance Center, a
separate system of payment has
been arranged. 0 2000
4. PREFACE
This volume contains the proceedings of the Fourth International Symposium on
Recycling of Metals and Engineered Materials. Since its inception, this quintennial series has
served as that year's TMS Fall Extractive Process Metallurgy Meeting, as it will this year in
conjunction with Lead-Zinc 2000. As in past meetings, this symposium will provide a forum
for technologists to discuss fundamental and practical topics related to recycling of many
materials.
The importance of recycling, waste reduction, and resource management to society and
industry has continued to grow since the first meeting in this series was held in 1985, spurring
an increase in the technical scope and the number of papers presented at the meeting. This
year, due to the impact of combining the symposium with Lead-Zinc 2000, the secondary lead
and zinc programs have grown significantly. The aluminum scrap processing portion of the
symposiumhas continuedto grow.
New to the symposium are sessions devoted to Electric Arc Furnace (EAF) Dust
Processing, and recycling of Consumer Batteries, Electronics/PlatingBy-products, Magnesium
and Refractories. The EAF dust program has attracted wide interest, with papers devoted to
theory and practice contributedby a large group of internationalexperts.
The editors and organizing committee, listed on subsequent pages, thank the authors for
providing the excellent papers contained herein. We recognize the time and effort required to
write strong technical papers. We also wish to thank the members of the Joint Recycling
Committee of the Extractive Processing and Light Metals Divisions of TMS for their
suggestionsand assistance in identifiing prospective authors. We also expresq our appreciation
to Ms. Terry Bauman for her diligent efforts and long hours in helping to assem%lethis volume.
Finally, we acknowledge and appreciate the efforts of Michael Packard, Peggy Weiss, Dane
Semonian,and the rsst of the TMS staff for their guidanceand support.
Donald L. Stewart,Jr.
Alcoa Inc.
Alcoa Center,Pennsylvania
James C. Daley
Daley & Associates
Phoenix, Arizona
Robert L. Stephens
ComincoResearch
Trail,B.C., Canada
5. ORGANIZING COMMITTEE
PLENARY SESSION
Donald L. Stewart, Jr. James C. Daley Robert L. Stephens
Alcoa Inc. ' Daley & Associates Cominco Research
Alcoa Center, Pennsylvania Phoenix, Arizona Trail, British Columbia, Canada
GENERALRECYCLING
James C. Daley
Daley & Associates
Phoenix, Arizona
Robert L. Stephens
ComincoResearch
Trail, British Columbia, Canada
SECONDARYLEAD
Andreas Siegmund Richard Leiby
RSR TechnologiesInc. East Penn ManufacturingCo.
Dallas, Texas Lyon Station,Pennsylvania
SECONDARYZINC
Larry L. Parkinson
Interamerican Zinc, Inc.
Coldwater, Michigan
StephenE. James
Big River Zinc Corp.
Sauget, Illinois
CONSUMER BATTERY RECYCLING
Robert L. Stephens
Cominco Research
Trail, British Columbia, Canada
EAF DUST PROCESSING
James C. Daley
Daley & Associates
Phoenix, Arizona
Dale A. Zuck
Consultant
Allen, Texas
vii
6. SECONDARY COPPER,NICKEL,COBALT
Larry M. Southwick
L. M. Southwick& Associates
Cincinnati, Ohio
Kunibert Hanusch
Hiittenwerke Kayser
Liinen, Germany
ELECTRONICS/PLATINGBY-PRODUCTSRECYCLING
Paul B. Queneau,
P. B. Queneau & Associates
Golden, Colorado
Lee Wilmot
HADCO Corp.
Salem,New Hampshire
PRECIOUSMETALS
Robert L. Stephens
Cominco Research
Trail, British Columbia, Canada
SPENT CATALYST RECYCLING
Robert L. Stephens
Cominco Research
Trail, British Columbia, Canada
ALUMINUM SCRAP RECYCLING
Ray D. Peterson
IMCO Recycling, Inc.
Rockwood, Tennessee
Jan H. L. van Linden
Recycling Technology Services
Edgewood, Pensylvania
ALUMINUMDROSS PROCESSING
Han Spoel
DrossTec, Inc.
Pittsburgh, Pennsylvania
Annette S. Revet
Kalium Chemicals, Ltd.
Regina, Saskatchewan,Canada
ALUMINUM BY-PRODUCT RECOVERY
JohnN. Hryn
Argonne National Laboratory
Argonne, Illinois
John W. Pickens
Alumitech Inc.
Streetsboro, Ohio
viii
7. AUTOMOTIVERECYCLING
Donald L. Stewart, Jr. Edward J. Daniels Robert L. Stephens
Alcoa Inc. ArgonneNational Laboratory Cominco Research
Alcoa Center, Pennsylvania Argonne, Illinois Trail, B.C., Canada
MAGNESIUMRECYCLING
James C. Daley
Daley & Associates
Phoenix, Arizona
Robert E. Brown
MagnesiumMonthly Review
Prattville,Alabama
REFRACTORYRECYCLING
Charles E. Semler
SemlerMaterial Services
Tucson, Arizona
Jeffrey B. Gorss
Alcoa Inc.
Knoxville,Tennessee
i
x
8. CONTENTS
Preface ........................................................................................................................................... ..v
..
Organizing Committee.................................................................................................................. vii
I -PLENARY SESSION
Technology Commercializationin the New Millenium:
Lessons from the Previous Millennium
L. M Southwick ................................................................................................................... 3
The Importance of Recycling to the Environmental Profile
of Metal Products
K J Martchek..................................................................................................................... 19
I1-GENERAL RECYCLING
An ImprovedNon-Conventional Method for ObtainingNuclear Pure
Uranium Oxides and Uranium Tetrafluoride from Actual Mill Strip Solution
L. A. Guirguis and H, K. Fouad......................................................................................... 31
Processing of Televisionsby Mechanical Separation Techniques:
Implications for Future Work in Product Design and Recycling
J M Krowinkel and W.L. Dalmijn ................................................................................... 47
I11- SECONDARY LEAD
Operations at the Doe Run Company’s Buick Resource Recycling
Division
J A. Moenster and M J Sankovitch ................................................................................. 63
Operation of a High-Output, One-Pass Smelting Systemfor Recycling
Lead-Acid Batteries
M Vondersaar and B. Bulnes .......................................................................................... ..73
Technology for Processing of Lead-Acid Batteries at Mulden-Hutten
Recycling Und Umwelttechnik GmBH
H.-P. Behrendt .................................................................................................................. .79
Recovery of Polypropylene from Lead-Acid Battery Scrap
G. Martin and A. Siegmund ............................................................................................... 93
Sulfur Injection to Remove Copper from Recycled Lead
G. Plascencie-Barrera, A. Romero-Serrano. R. D. Morales
S. Gonzalez-Ldpez, F. Chavez-Alcala, and D. Silva-Galvan.......................................... .lo3
xi
9. Waste-LessTechnology for Processing of SubgradeLead
Concentratesand Flotation Middlings ContainingPrecious Metals
A.V. Tarasov and A. D. Besser ........................................................................................ 117
Modernisationof the Lead Acid Battery Scrap Smelting Technology
at “Orzel Bialy” S.A.
S. Gizicki, Z. Smieszek, J. Dzernecki, G.Krawiec, J. Porqnbski,
W. Dqbrowicz, andJ. Pawlowski ..................................................................................... 123
Reductionof Lead in the SeparatorFraction
U. Kammer and H. Muller .............................................................. ./.
.............................. .133
The Role of Electrochemistry at East Perm Manufacturing
R. Leiby, M. Bricker, and R. A. Spitz ............................................................................... 141
Viscosity Measurements of Lead Slags
R. G. Reddy and Z. Zhang................................................................. ,............................. .153
CTP’s Experience in the Removal of Contaminants and Odors
in the Recycling Industry -A New Process for Simultaneously
RemovingVOCs and Dioxins and Furans
H. Thalhammer................................................................................. .,.
............................. 165
IV -SECONDARYZINC
The Need to Recycle Zinc: A Considerationof Public
Perception,Politics and Competitiveness
D. R. Parker ..................................................................................................................... 177
ElectrolyticZinc Recovery in the EMEW@Cell
P. A. Treasure.................................................................................................................. 185
Zinc RecyclingVia the Imperial SmeltingTechnology-Latest
Developmentsand Possibilities
B. Schwab and W.-D.Schneider...................................................... .,
............................... 193
Dezincing of Zinc Coated Steel Scrap: Current Situation at
Saint-SaulveDezincing Plant of CompagnieEuropeenne
De Dezingage (C.E.D.)
D. Groult, R. Mare‘challe,P. Klut, and B. T. H. Bonnema.............................................. 201
Recovery of Zinc from Zinc Ash and Flue Dust by
PyrometallurgicalProcessing
M A. Barakat................................................................................................................... 211
xii
10. V -EAF DUST PROCESSING
Recovering Zinc and Lead from Electric Arc Furnace Dust:
A Technology StatusReport
A.D. Zunkel ...................................................................................................................... 227
The Current Status of Electric Arc Furnace Dust Recycling in
North America
M Liebman ...................................................................................................................... 237
Reclamation of Valuable Metals'from Hazardous Waste
E. C. Cernak and A. J. Maselli ........................................................................................ 251
Fundamental Study of Fe-Zn Intermetallic Compounds for Zinc
Evaporation from Galvanized Steel Sheet
K. Mita, T. Ikeda, andM Maeda..................................................................................... 261
Characterisation and Removal of Halogewin the EAF Dust and
Zinc Oxide Fume Obtained from'Phehal Treatment of EAF Dust
G. Ye................................................................................................................................. 271
Upgrading of EAF Dust by Injection into Iron and Steel Melts
D. Colbert and G.A. Irons............................................................................................... 281
Volatilization Kinetics of Zinc and Lead in Zn-Pb Bearing Dust
Pellets Containing Carbon
D. Y.Wang,X L. Shen, D. R. Gu, and G. Y.Sha ............................................................ 297
Turning Blast Furnace Dust Into a Source of Zinc and Lead Units:
A Progress Report on Testwork at Corns Ijmuiden
S. Honingh, G. Van Weert, and M. A. Reuter ................................................................. .313
Recovery of Zinc Oxide from Secondary Raw Materials: New
Developments of the Waelz Process
K. Mager, U.Meurer, B. Garcia-Egocheaga, N. Goicoechea,
J. Rutten, W.Saage, and F. Simonetti.............................................................................. 329
Operational Practice with the Waelz Kiln and Leaching Plant of
TSU in Taiwan
A.L. Beyzavi and C. Mattich ............................................................................................ 345
Production of CrudeZinc Oxide from Steel Mill Waste Oxides
Using a Rotary Hearth Furnace
I/: R. Daiga and D. A Home ............................................................................................ 361
Processing of Zinc-Containing Wastes with the Liquid-Phase
Reduction Romelt Process
I/: Valavin, K Romenets, Y.Pokhvisnev, S. Vandariev,
and A. Yatshenko-Juk...................................................................................................... 369
xiii
11. Electrolytic Zinc Production from Crude Zinc Oxides with the
EzinexB Procress
M Olper and M Maccagni ............................................................................................. 379
Processing Steel Wastes Pyrometallurgically at INMETCO
K. L. Money, R. H. Hanewald, and R. R. Bleakney ......................................................... 397
Treatment of SecondaryZinc Oxides for Use in an
Electrolytic Zinc Plant
S. S. Chabot and S. E. James ........................................................................................... 409
EAF Dust Recycling at Ameristeel
J. D. Sloop........................................................................................................................ 421
Recycling EAF Dust with CONTOPB Technology
F. Sauert, U. Kerney, andJ. Pesl .................................................................................... 427
VI - SECONDARY COPPER, NICKEL, COBALT
Recovery of Copper from Effluents by Supported Liquid Ion
Exchange Membranes- From Laboratory Scale to an
Integrated Pilot Plant
J. VanderLinden, R, De Ketelaere, and M Verhaege .................................................... 445
Copper and Zinc Recovery with Emulsion Membranes from Mine
Waste Waters
D. N. Nilsen and G. L. Hundley ....................................................................................... 455
Laboratory and Pilot Plant Processing of SpentNi-Cd Batteries
M Cavallini, C. Lupi, D. Pilone, P. P. Milella, A. Pescetelli,
and G. Cannavale ............................................................................................................ 471
Preparation of Nickel Sulfate from SpentNickel-Cadmium Batteries
J . 3 Sohn, K.-H Park, J.3. Park, and H.-S. Jeon .......................................................... 479
Recycling Metals Using the MOCVD Process
D. S. Terekhov and M 0'Meara ..................................................................................... 487
Removal of Copper from Slag with the Aid of Reducing and
Sulfiding Gas Mixtures
A. V. Tarasov and S. D. Klushin ...................................................................................... 493
Electroslag Melting for Recycling Scrap of Valuable Metals and Alloys
T;: V. Satya Prasad and A. Sambasiva Rao ...................................................................... 503
Melt Refining of Grinding Sludge Containing Cobalt and Nickel in an
ESCR Furnace
V. M Sokolov andJ. J. DuPlessis, Jr. ............................................................................. 517
xiv
12. The Use of Secondary Copper for the Production of Rods and
Tubes by Continuous Casting in an Electron-Beam Installation
S. J! Ladokhin and I? B. Chernyavsky ............................................................................ 529
Lead Sulfate Scale in a Copper SmelterAcid Plant
J. M Rapkoch .................................................................................................................. 537
Recollections of Operations at a Secondary Copper Smelter
And Refinery: The U.S. Metals Refining Company, Carteret,NJ
J. E. Hoffman ................................................................................................................... 551
Sampling of FSD-Type Cathodes Made from Recycled Copper
P. Barrios, A. Alonso, and U Meyer ............................................................................... 567
Arsenic Sludge Recycle at Caraiba Metais S.A.
J L. R. Bravo and D. C.Foguel ....................................................................................... 5a3
VII- CONSUMER BATTERY RECYCLING
Recycling of Mobile Phone Batteries Using the Ausmelt Catalytic
Waste Converter
J Sofia andJ. Fogarty .................................................................................................... 597
Zimaval (Zinc Manganese Valorization) Technology for Recycling
Of Batteries and Other Complex Zinc Bearing Materials
S. Ferlay.......................................................................................................................... .613
The Oxyreducer Technology - A New Technology to Recycle Metal
Containing Waste
A. Antensen, R. Burri, and D. Villette.............................................................................. 625
VIII -ELECTRONICSPLATING BY-PRODUCTS RECYCLING
CommercialPractices of US. Specialty Recycling Operations
D. J. Cassidy .................................................................................................................... 637
Development and Manufacture of an Innovative Mineral Feed
Ingredient Produced from Recycled Copper
F. A. Steward ................................................................................................................... 643
Electrochemical Treatment of Spent Electroless Nickel Solution
R. Mack0 and T. Mason ................................................................................................... 655
Recycling of TidLead Bearing By-products from the ElectronicsIndustry
A. N Aposhian ................................................................................................................. 661
XV
13. Success Storiesof an Innovative Water RecyclingMethod Using
Carbon Adsorptionto Recover Heavy Metals from Industrial
Wastewater
T.Lewis.,......................................................................................................................... .665
Lead Removal by Ion Exchange
P. Meyer, L. Gottlieb, and F. DeSilva ............................................................................. 675
IX -PRECIOUSMETALS RECYCLING
The Rebirth of UMPM Hoboken -Executive Summary
D. Kennis ......................................................................................................................... 689
Metal Recyclingat Kosaka Smelter
Y Maeda, H. Inoue, S. Kawamura, and H.Ohike........................................................... 691
Ausmelt Technologyfor Recycling of Computer Boards and
Other High Value Materials
R. W.Matusewicz and B. R. Baldock ............................................................................... 701
RecyclingUsed Photographic Chemicals into High Quality
Fertilizer
J W. Whitney................................................................................................................... 711
Precious Metal Recovery with Electronically Conducting
Polymers
M Savic, A. C. Cascalheira, and L. M Abrantes............................................................ 723
A New Technology for the Processing of Precious Metal
Containing SecondaryRaw Materials
0.Y Goriaeva, V. I. Skorohodov, S. S. Naboychenko,
and M A. Verhaege ......................................................................................................... 731
X -SPENT CATALYST RECYCLING
Recovery of Non-Ferrous Metals from Spent Catalysts
C. S, Brooks ..................................................................................................................... 741
Evolution of GCMC’s Spent Catalyst Operations
Z. R. Llanos and W. G. Deering....................................................................................... 759
Novel DC Furnace Design for SmeltingNickel and Cobalt Bearing
Concentratefrom Spent Alumina Catalyst
S. de Vries,N. Voermann, T.Ma, B. Wasmund,J Metric,
and S. Kasinger................................................................................................................ 773
xvi
14. Recovery of Vanadium, Molybdenum,Nickel, and Cobalt from
Spent Catalysts: A New Processing Plant in China
M.-I? Wang...................................................................................................................... 781
Reactor Design for Nickel Recovery from HDS Waste Catalyst
G. Plascencia-Barrera, J. G. Gutie'rrez-Paredes,and
F. Reyes-Carmona ........................................................................................................... 795
XI- ALUMINUM SCRAP RECYCLING: SCRAP PREPARATION AND PROCESSING
Aluminum Scrap Supply and Environmental Impact Model
P. R. Bruggink.................................................................................................................. 809
Continuous Measurement of UBC Decoating Efficiency
W~D. Stevens, G. Riverin, and C. Simard ....................................................................... 823
A Basic Study on Development of a Swell-Peeling Method in
UBC Recycling System
K. Fujisawa, T. Kogishi, K. Oosumi, and T. Nakamura .................................................. 835
Aluminum Recycling Via Near Room Temperature Electrolysis
In Ionic Liquids
B. Wu,R. G. Reddy, and R. D. Rogers............................................................................. 845
Transportation of Molten Aluminum
R. D. Peterson and G. G. Blagg....................................................................................... 857
XI1 - ALUMINUM SCRAP RECYCLING: MELTING TECHNOLOGY
Explosions During Aluminum Scrap Melting in the Recycling Industry-
Causes and Prevention
J. E. Jacoby ...................................................................................................................... 869
MeltSim: Melting Optimizationfor Aluminum Reverb Furnaces
R. A
4 Alchalabi, C. S. Henkel, F. L. Meng, and1 Chalabi............................................. 877
A Vertical Floatation Melter for Decoating and Melting ScrapAluminum
R. DeSaro, W.Bateman, and R. Jain............................................................................... 887
An Innovative Stack Melter for Use in the Aluminum Casting Industry
E. Kear, R. Rosenthal, R. DeSaro, and N, Schwartz........................................................ 901
Thermal Dynamic VisualizationModeling and Optimization of
Aluminum Sidewell Melting Furnaces-Executive Summary
C. T. Vild...................................................................................... ................................... 909
xvii
15. The Use of Electro-Magnetic Pumping for Melting and Circulation
of Aluminiumto Provide Production and Quality Benefits to the
Aluminium Cast House - - Abstract
A. M. Peel......................................................................................................................... 915
XI11 -ALUMINUM SCRAPRECYCLING:QUALITY CONSIDERATIONS
The Importanceof Metal Quality in Molten SecondaryAluminum-
Executive Summary
C.E. Eckert andB. Cochran ........................................................................................... 919
Recycling-A Fan of the Can
X B. Steverson ................................................................................................................ 923
Developmentof New Filter for Removal of Non-Metallic Inclusions
From the Molten Aluminum
K. Oosumi,I
:Nagakura, R. Masuda, I
: Watanabe,and ir: Ohzono...............................951
Refining Aluminium Scrap by Means of Fractional Crystallisation:
Basic Experimental Investigations
X H Sillekens, J: A. F. A
4 Schade Van Westrum,
0.S. L. Bruinsma, B. Mehmetaj, and M. Nienoord......................................................... 963
Refining of a 5XXX Series Aluminum Alloy Scrap by Alcoa
Fractional CrystallizationProcess
A. I. Kahveci and A. Unal................................................................................................ 979
A New Proposal of Continuous Agitation Vacuum Distillation
Process (CAVP)to Remove Zn from Aluminum Scrap Melt
A
4 Ohtaki, T.Arakawa, and F. Murata........................................................................... 993
XIV -ALUMINUM SCRAP RECYCLING:PROCESS ANALYSIS
UBC Recycling Complex Mass Balance
R. F. Jenkins and K. G. Robertson................................................................................. 1007
Commercial Scale Melt Loss Testing -Executive Summary
D. L. Stewart, Jr............................................................................................................ 1029
Dross Analysis Methods and Their Application for Evaluating
SecondaryFurnace Operations
R. D,Peterson and A. S. Revet....................................................................................... 1035
Aluminum Sidewell Melting Furnace Heat Transfer Analysis
R. F.Jenkins.................................................................................................................. .lo45
xviii
16. Historical Data Analysis in Quality Improvement of Aluminum
Recycling Process
A. R. Khoei, I. Masters, and D. T.Gethin...................................................................... 1063
Experimental Study on Aluminum Scrap Recycling
Y: Xiao, M Reuter, P. Vonk,J. Vonken,H Orbon,
T. Probst, and U. Boin ................................................................................................... 1075
Metal Values from Used Beverage Cans
M A. Rabah ................................................................................................................... 1089
XV -ALUMINUM DROSS PROCESSING
Cold Cleaning and Concentratingof Non-Ferrous Dross
D. J. Roth and P. G. Schirk............................................................................................ 1105
Numerical Modelling of a Rotary Aluminum Recycling Furnace
S. B. Davies, I. Masters, and D. T. Gethin..................................................................... 1113
Dross Reclamation at Aluminum Melting Furnace Sites
A. E. Groteke.................................................................................................................. 1123
Drosrite Salt-Free Processing of Hot Aluminum Dross
M G. Drouet, R. L. LeRoy, and P. G. Tsantrizos.......................................................... 1135
Improvements in Scrap Recycling and Dross Processing Using Oxygen
R. J. Hewertson .............................................................................................................. 1147
XVI -ALUMINUM BY-PRODUCTRECOVERY
Regulatory Issues Associated with Salt Cake and Dross Processing
In USA and Europe - - Abstract
J. N. Hryn, E. J. Daniels, M Askew, and G. Kirchner .................................................. 1157
ElectrodialysisTechnology for Salt Recovery from Aluminum
Salt Cake Waste Brines
A. K. Krumdick, D. J. Graziano, andJ h? Hryn ........................................................... 1159
Reclaiming Salt Flux from Aluminum Salt Slag Wastes
Process Design -Product Performance
R. M Russell and J: Sweeney......................................................................................... 1171
Eddy Current Separationof Aluminum SmeltingBy-products - - Abstract
J. Y: Hwang, R. C. Greenlund, M Jeong, A. A
4 Hein,
D. C. Popko, R. D. Peterson, and R. McChesney .......................................................... 1181
xix
17. Aluminum Plasma Dross Treatment Process and Calcium
AluminqteProduction: Closing the Loop with No Residue
R. Breault, D. Guay, G. Dub&,D. Legault, R. Morin,
K. Annett, and J. Bonneau ............................................................................................. 1183
Assuring the Benefits of Aluminum Recycling: Engineering
Economical Environmental Solutionsto the Issues of Black Dross
and Saltcake
J W.Pickens .................................................................................................................. 1195
R&D on Treatment and Recycling of Dross Residue
A
4 Tougo, M. Tokunoh, F. Chiba, and T. Kisaragi ....................................................... 1209
Conversion of Aluminium Industry Wastes into Glass-
Ceramic Products
G.Balasubramanian, M. T. Nimje, and V. V. Kutumbarao........................................... 1223
XVII -AUTOMOTIVE MATERIALS RECYCLING
Opportunities for Recycling Aluminum from Future Automobiles - - Abstract
M Thomas ..................................................................................................................... 1231
Scrap Preparation for Aluminum Alloy Sorting
A. Gesing, C.Stewart, R. Wolanski, R. Dalton, and L. Berry........................................ 1233
ThermomechanicalTreatments for the Separation of Cast and Wrought
Aluminum
D. Maurice, J. A. Hawk, and W. D. Riley .............
).(
....................................................... 1251
Sensor Controlled Quality Control and Sorting of ScrapAluminium
Alloys
T. P. R. De Jong, H. U. R. Kattentidt, and W.L. Dalmijn............................................. 1263
Materials Recovery from ShredderResidues
E. J Daciels, B. J Jody, andJ. Pomykala, Jr. .............................................................. 1277
Recycling Plastics Scrap and ASR: The Simplicity of Automotive
Recycling
I. VanHerpe................................................................................................................... 1285
A Novel Approach to the Mechanical Processing of ASR
N Fraunholcz, E. A. Schokker, P. C. Rem, and W.L. Dalmijn .......................... ........1303
xx
18. XVIII -MAGNESIUM RECYCLING
Magnesium Recycling Yesterday, Today, Tomorrow
R. E. Brown.................................................................................................................... 1317
Addressing Some of the Key Recycling Issues in the Magnesium
Industry with Integration of Primary Metal Production,Die
Casting and Recycling
M. Rejaee and P. Steeneken.......................................................................................... .1331
Preparation of SecondaryMagnesium for Use in Hot Metal
Desulfurization
M R. Dahm.................................................................................................................... 1333
Remelting of Magnesium Type 1 ScrapWith or Without Flux?
A. Ditze and C. Scharf ............................................................................................ ......1341
XIX -REFRACTORYRECYCLING
Overviewof RefractoryRecycling -- Executive Summary
R. T. Oxnard................................................................................................................... 1351
Spent RefractoryRecyclingAXeuseEfforts in the Steel and
AluminumIndustries
J P. Bennett and K.-S. Kwong...................................................................................... .1353
Modeling the Reuse of SpentBasic RefractoryMaterial in an EAF
J Kwong andJ. P. Bennett......................................................................................... ...1369
Spent RefractoryWaste RecyclingfromNon-Ferrous Metals
Manufacturers in Missouri
J D. Smith and K. D. Peaslee........................................................................................ 1385
Author Index.............................................................................................................................. 1395
xxi
19. Edited by D.L.Stew-, Jr., J.C. Daley and R.L.Stephens
1.395
A
Abrantes, L. M., 723
Alchalabi,R. M., 877
Alonso, A., 567
Annett, K., 1183
Antensen, A., 625
Aposhian,A. N., 661
Arakawa, T., 993
Askew, M., 1157
B
Balasubramanian, G., 1223
Baldock, B. R., 701
Barakat, M. A., 211
Barrios, P., 567
Bateman, W., 887
Behrendt,H.-P., 79
Bennett,J. P., 1353,1369
Berry,L., 1233
Besser,A. D., 117
Beyzavi, A.L., 345
Blagg, G. G., 857
Bleakney, R. R., 397
Boin, U., 1075
Bonneau, J., 1183
Bonnema, B. T. H., 201
Bravo, J. L. R., 583
Breault, R., 1183
Bricker,M., 141
Brooks, C. S., 741
Brown, R. E., 1317
Bruggink,P. R., 809
Bruinsma,0.S. L., 963
Bulnes, B. 73
Burri, R., 625
C
Cannavale, G., 471
Cascalheira,723
Cassidy,D. J., 637
Cavallini,M., 471
Cernak, E. C., 251
Chabot, S. S., 409
AUTHOR INDEX
Chalabi,I., 877
Chavez-Alcala,F., 103
Chemyavsky,V. B., 529
Chiba,F., 1209
Cochran, B., 919
Colbert, D., 281
D
Dqbrowicz, W., 123
Dahm, M. R., 1333
Daiga,V. R., 361
Dalmijn,W. L., 47,1263,1303
Dalton, R., 1233
Daniels, E. J., 1157, 1277
Davies, S.B., 1113
De Jong, T. P. R., 1263
De Ketelaere, R., 445
de Vries, S., 773
Deering, W. G., 759
DeSaro, R., 887,901
DeSilva,F., 675
Ditze, A., 1341
Drouet, M. G., 1135
DubC, G., 1183
DuPlessis, Jr., J. J., 517
Dzernecki,J., 123
E
Eckert, C. E., 919
F
Ferlay, S., 613
Fogarty,J., 597
Foguel,D. C., 583
Fouad, H. K., 31
Fraunholcz,N., 1303
Fujisawa, K., 835
G
Garcia-Egocheaga,B., 329
Gesing, A., 1223
Gethin,D. T., 1063,1113
Gizicki, S., 123
Goicoechea. N.. 329
20. Fourth International Symposiumon
Recycling of Metals and EngineeredMaterials
1,396
Gonziilez-L6pez,S., 103
Goriaeva,0.Y., 731
Gottlieb,L., 675
Graziano,D. J., 1159
Greenlund,R. C., 1181
Groteke,A. E., 1123
Groult, D., 201
Gu, D. R., 297
Guay,D., 1183
Guirguis, L. A., 31
Gutierrez-Paredes,J. G., 795
H
Hanewald,R. H., 397
Hawk, J. A., 1251
Hein, A. M., 1181
Henkel, C. S., 877
Hewertson,R. J., 1147
Hoffman, J. E., 551
Honingh, S., 313
Home, D. A., 361
Hryn, J.N., 1157,1159
Hundley, G. L., 455
Hwang, J. Y., 1181
I
Ikeda,T., 261
Inoue, H., 691
Irons, G. A., 281
J
Jacoby,J. E., 869
Jain, R., 887
James, S. E., 409
Jenkins,R. F., 1007,1045
Jeon, H.-S., 479
Jeong, M., 1181
Jody, B.J., 1277
K
Kahveci, A. I., 979
Kammer, U., 133
Kasinger, S., 773
Kattentidt, H. U. R., 1263
Kawamura, S., 691
Kear, E., 901
Kennis, D., 689
Kerney,U.,427
Khoei, A. R., 1063
Kirchner, G., 1157
Kisaragi, T., 1209
Klushin, S. D., 493
Klut, P., 201
Kogishi, T., 835
Krawiec, G., 123
Krowinkel, J. M., 47
Krumdick, A. K., 1159
Kutumbarao,V. V., 1223
Kwong, J., 1369
Kwong, K.-S., 1353
L
Ladokhin, S.V., 529
Legault,D., 1183
Leiby,R., 141
LeRoy,R. L., 1135
Lewis,T., 665
Liebman, M., 237
Llanos, Z. R., 759
Lupi, C., 471
M
Ma, T.,773
Maccagni, M., 379
Macko, R., 655
Maeda, M., 261
Maeda,Y., 691
Mager, K., 329
Marechalle, R., 201
Martchek, K J., 19
Martin, G., 93
Maselli, A. J., 251
Mason, T., 655
Masters, I., 1063, 1113
Masuda, R., 951
Mattich, C., 345
Matusewicz,R. W., 701
Maurice, D., 1251
McChesney,R., 1181
Mehmetaj, B., 963
Meng,F. L., 877
Metric, J., 773
Meurer, U.,329
Meyer,U., 567
Meyers,P., 675
Milella,P. P., 471
Mita, K., 261
Moenster, J. A., 63
21. Edited by D.L. Stewart, Jr., J.C. Daley and R.L.Stephens 1,397
Money,K. L., 397
Morales, R. D., 103
Morin, R., 1183
Muller, H., 133
Murata,F., 993
N
Naboychenko, 731
Nagakura,Y.,951
Nakamura, T., 835
Nienoord, M., 963
Nilsen, D. N., 455
Nimje, M. T., 1223
0
O’Meara, M., 487
Ohike, H., 691
Ohtaki, M., 993
Ohzono,T., 951
Olper, M., 379
Oosumi,K., 835,951
Orbon, H., 1075
Oxnard,R. T., 1351
P
Park, J.-S., 479
Park, K.-H., 479
Parker, D. R., 177
Pawtowski, J., 123
Peaslee, K. D., 1385
Peel, A. M., 915
Pescetelli,A., 471
Pesl, J., 427
Peterson, R. D., 857, 1035, 1181
Pickens,J. W., 1195
Pilone, D., 471
Plascencia-Barrera, G., 103,795
Pokhvisnev,Y., 369
Pomykala,Jr., J., 1277
Popko, D. C., 1181
Porqmbski,J., 123
Probst, T., 1075
R
Ribah, M. A., 1089
Rapkoch, J. M., 537
Reddy, R. G.,
153,845
Rejaee, M., 1331
Rem, P. C., 1303
Reuter, M. A., 313, 1075
Revet, A. S., 1035
Reyes-Carmona,F., 795
Riley, W. D., 1251
Riverin, G., 823
Robertson, K. G., 1007
Rogers, R. D., 845
Romenets,V., 369
Romero-Serrano,A., 103
Rosenthal, R., 901
Roth, D. J., 1105
Russell, R. M., 1171
Rutten, J., 329
S
Saage,W., 329
SambasivaRao, A., 503
Sankovitch,M. J., 63
SatyaPrasad,V. V., 503
Sauert,F., 427
Savic, M., 723
SchadeVan Westrum,J. A. F. M., 963
Scharf, C., 1341
Schirk,P. G., 1105
Schneider,W.-D., 193
Schokker, E. A., 1303
Schwab,B., 193
Schwartz,N., 901
Sha, G. Y., 297
Shen,X. L., 297
Siegmund,A., 93
Sillekens, W. H., 963
Silva-Galvan,D., 103
Simard, C., 823
Simonetti,F., 329
Skorohodov,V. I., 731
Sloop, J. D., 421
Smieszek,Z., 123
Smith, J. D., 1385
Sofra,J., 597
Sokolov,V.M., 517
Southwick,L. M., 3
Spitz,R. A., 141
Steeneken,P., 1331
Stevens, W. D., 823
Steverson,W. B., 923
Steward,F. A., 643
Stewart, C., 1223
Stewart, Jr., D. L., 1029
Sweeney,J., 1171
Soh, J.-S., 479
22. 1,398
T
Tarasov,A.V., 117,493
Terekhov,D. S.,487
Thalhammer, H., 165
Thomas, M., 1231
Tokunoh,M., 1209
Tougo,M., 1209
Treasure,P. A., 185
Tsantrizos,P. G., 1135
U
Unal, A.,979
V
Valavin,V.,369
VanHerpe, I., 1285
VanWeert,G., 313
Vandariev,S.,369
VanderLinden,J., 445
Verhaege,M. A.,445,731
Vild, C.T.,909
Villette,D., 625
Voermann,N., 773
Vondersaar,M., 73
Vonk,P., 1075
Vonken,J., 1075
W
Wang, D.Y.,297
Wang,M.-V.,781
Wasmund,B., 773
Watanabe,Y.,951
Whitney,J. W., 711
Wolanski,R., 1223
Wu, B., 835
X
Xiao, Y.,1075
Y
Yatshenko-Juk, A.,369
Ye,G
.
,
271
Fourth International Symposium on
Recycling of Metals and EngineeredMaterials
z
Zhang, Z., 153
ZunkeI, A.D.,
227