September 2014 Newsletter - ASM International Central
Transcription
September 2014 Newsletter - ASM International Central
Central Massachusetts Chapter Newsletter ASM International Central Massachusetts Chapter www.asm-ma.org September 2014 Volume 7, Issue 1 In this Issue Welcome to Our 20142015 Season! ........................ 1 2014-2015 Meeting Schedule .............................. 1 2014 ASM New England Materials Experience .......... 2 Announcing Our Autumn Course .................................. 3 Central Mass Chapter ASM Golf Outing - May 29, 2014 ................................ 4 Sustaining Member Company Benefits .............. 5 Chet Inman Award and MQP Award for WPI ............ 5 WPI Faculty News ................ 6 On a Musical Note…7 WPI Student News…….8 ASM Historical Landmark..9 Pollution-Eating Buildings…10 Contact Us ........................... 10 Welcome to Our 2014-2015 Season! I would like to welcome everyone to the 93rd season of the Central Massachusetts Chapter of ASM International. We are looking forward to an exciting year starting with a visit to the Quabbin Reservoir in September, the return of Bike Builders’ Night in October (including a pre-meeting bike ride), and a Joint Meeting with ASM-Boston at the Buehler Center of Excellence at BU in November As I begin my second year as Chair of the Central Massachusetts Chapter I look forward to building on the Sept. 24 Nov. 19 Jan. 21 A special thanks to our Sustaining Member companies: Feb. 18 Bodycote March 25 Buehler County Heat Treat Inc Exponent April 23 (Thursday) Fabrico Inc. Gallant Machine Works Inc. Hardline Heat Treating Inc. May 11 (Monday) Hayden Corporation Metlab Corporation MMR Group Inc. Peterson Steel Corporation United Service Company Worcester Polytechnic Institute As professionals who work with materials on a daily basis, we look at the structure-property relationships that make each of these materials possible. We use this approach to advance materials research and manufacturing and use it to improve the world around us. My challenge to our members is to pass on your passion for what you do to not only this generation of engineers and scientists but also the next generation of students. Thank you for your support of the Central Massachusetts ASM Chapter. Noah Budiansky 2014-2015 Chapter Chair Central Massachusetts Chapter – ASM International 2014-2015 Meeting Schedule Oct. 15 Excel Technologies Inc. success of last year and continuing our efforts to reach out to more local schools and recruit more members to participate in programs with local universities, high schools and grade schools. If we can connect with young students and get them excited about materials and materials engineering then we are paving the way for a future of limitless inventiveness. May 22 (Friday) Quabbin Staff Note Early Start Time: 3PM Mike Zanconato Student Night & Joint Meeting with ASM-RI Quabbin Visitor Center Belchertown, MA VFW Hall Millbury, MA Scott Prenovitz Demonstration & Talk TBD Joe Strauss Ryan Dailey Spouses & Guests Night Providence & Worcester Railroad Tour of Repair Facility with Staff Joint Meeting with ASM-RI ASM Trustee Speaker Prof. Ravindran ASM President ASM National Trustee Speaker & Awards Night O’Connor’s Worcester, MA Top 3 finalist teams Student Night & Past Chairs' Night O'Connors Worcester MA N/A Materials Science: High School Students Frank Blanchard Golf & Officer Elections Quabbin Reservoir: History & Engineering Bike Builders Night & Bike Ride Forefront of Metallography 3D Printing: Jewelry & Prosthetics WPI Undergraduate Major Qualifying Project Poster & Presentation Competition 10th Annual ASM International Materials Experience New England Annual Golf Outing O'Connor's Worcester, MA Worcester, MA Dinner at Dino’s Worcester Polytechnic Institute, Worcester, MA Heritage Country Club, Charlton MA 2014 ASM New England Materials Experience This year was the 9th annual New England Materials Experience at WPI and the 3rd annual at Boston University. These events are jointly sponsored and organized by the Central Massachusetts, Boston, Rhode Island and Northern New England Chapters of ASM. Students, teachers and parents enjoyed learning about many facets of the world of Materials Science & Engineering. Students learned about selecting materials to design a bicycle helmet using chocolate to simulate the brain during impact. They also learned about superconductivity and turned bananas into hammers with liquid nitrogen. Students learning about materials selection for impact resistance The WPI Materials Experience took place on Monday, May 12th with students from 10 different high schools in Massachusetts and Rhode Island. Students began the day with an introduction from Professor Jianyu Liang. She introduced the students to how materials impact their lives every day and then served ice cream made with liquid nitrogen right there in the lecture hall! Chuck Innis playing guitar in the Musical Materials Module Jianyu Liang starts with ice cream! The students were divided into eight groups to attend each of the different modules, including cryogenics, shape memory alloys, musical materials, polymers, fatigue, mechanical behavior, hydrogels, and electron microscopy. At each of these stations, students were able to experience a different aspect of materials science ranging from experiments like smashing cryogenically frozen flowers and racquet balls to the life-saving applications of hydrogels and shape memory alloys. Over lunch students were able to talk with graduate students, professors, and professionals from the Materials World. Jeff Kablik repairing a pig lung with hydrogels The day closed with a talk and demonstration by Fay Butler. Fay combines materials science, engineering, machining, design and art in his work with automobile, motorcycle and car designers around the world. Thank you to the professionals and WPI students who volunteered to make this day phenomenal! Special Thanks to our Sponsors: Boston University Buehler Corporation Beaver-Visitec International Bodycote, Inc. C. R. Bard Dynamet Technology, Inc. Dynamic Flowform Corporation Geller Microanalytical, Inc. Genzyme Corporation H. C. Starck Hitchiner Manufacturing Co. Instron Corporation JEOL Corporation Medtronic Skyworks Solutions, Inc. Surmet Corporation Spectrum Thermal Processing Worcester Polytechnic Institute ASM Boston Chapter ASM Central Massachusetts Chapter ASM Northern New England Chapter ASM Rhode Island Chapter ASM Materials Education Foundation 2 Announcing Our Autumn Course 3 Central Mass Chapter ASM Golf Outing - May 29, 2014 For as long as we can remember, the Central Massachusetts (Worcester) Chapter has sponsored a golf outing. In the early years, this was well attended but then attendance started to dwindle. In 1993, Frank Blanchard breathed new life into the golf outing by suggesting that it be more than a social outing for ASM. Frank transformed the golf outing into a competition involving local and out-ofstate companies. The result is that we now have 60 or more golfers out on the course competing to win the right for their company’s name to be engraved on the ASM-CM Golf Outing Plaque alongside previous victorious teams. 2014 marked the 23-year milestone of the ASM-CM Golf Outing. Seventeen teams competed for the honor of adding their company name to the Worcester ASM Golf Outing Plaque. The winning team in 2014 was United Service Company, Inc. Longest Drive Scott Prenovitz with Frank Blanchard We would like to give a special thank you to Eric Tessier from Gallant Machine in Worcester, MA for all the help he has given through the years. Also a big thank you to Joyce Hyde for all her effort in the success of this outing and to Kathy Trudeau for all the help the day of the outing. We would also like to thank all the companies who sponsored a tee sign and to all who have participated in this year’s outing. We look forward to seeing you for our next outing on May 22, 2015. Please note that this will be held on a Friday instead of the traditional Thursday. Remember that only one company representative is needed per team, and everyone leaves with a prize! Closest to the Pin John Elder with Frank Blanchard 1st Place Winners Rebecca Riberiro * Danny Riberiro Wayne Logee * Dan Lathope With Frank Blanchard Through the years we have been able to keep our entry fee very low while still offering a great steak dinner and terrific target holes along with other competitive challenges like the Las Vegas Hole. A nice touch to the outing is the free beer and hot dog for lunch. Special thanks to Frank Blanchard who organizes this great event every year! 4 Sustaining Member Company Benefits The ASM Central Massachusetts Chapter offers a unique opportunity for local companies in the materials industry to benefit from corporate membership. These benefits include: • • • • Membership for one individual (since Sustaining Membership is only $175 annually, this decreases the individual’s membership cost from $113 to $62). Discounted price for employees to attend local ASM courses held by the Central MA Chapter. A link from our website (www.asmma.org) to your company website. Are there benefits that you would like that aren’t listed? Please contact us with your suggestions at asmcmc@asm- ma.org. Our goal is to increase how Sustaining Memberships in ASM Central Massachusetts serve our sponsors. Thank you to our Sustaining Members: Bodycote Buehler County Heat Treat Inc Excel Technologies Inc. Exponent Fabrico Inc. Gallant Machine Works Inc. Recognition on our website of your company as a supporting Sustaining Member. Hardline Heat Treating Inc. Recognition of your company as a sponsoring Sustaining Member at the beginning of each monthly meeting’s technical presentation. MMR Group Inc. Hayden Corporation Metlab Corporation Peterson Steel Corporation United Service Company Worcester Polytechnic Institute Chet Inman Award and MQP Award for WPI In memory of Chester M. Inman, who helped to found the Worcester Chapter, this scholarship is presented annually by the Central Massachusetts Chapter of ASM International to a regional student in the field of metallurgy or materials science. Please join us in congratulating the winner of the 2014 Chet Inman Award, Aaron Birt, shown in the photo below on the left, receiving his award from Dr. Noah Budiansky, ASM-CM Chair 2013-2015. Undergraduate students at Worcester Polytechnic Institute must complete a Major Qualifying Project (MQP), under the guidance of academic advisors, in order to obtain their degrees. Ideally, the project synthesizes all previous study in order to solve problems and perform tasks in the chosen major field, with students striving to communicate results confidently and effectively. The Central Massachusetts Chapter of ASM International participates in the competition to select the best MQP presentation in the Mechanical Engineering department, with special emphasis on Materials research. ASM-CM provides judges who select the three top projects to present their work that evening at the Chapter dinner meeting. The three chosen finalist teams give brief presentations of the highlights of their projects and the ASM-CM members vote to choose the winner of a cash prize. Congratulations to the 2014 WPI MQP Competition Winners Jennifer Baker, Rebecca Draper, and Katie Monighetti shown above in the photo on the right. Their winning project: Injection Molding of Chocolate. 5 WPI Faculty News Professor Diana Lados Granted New NSF Award for development of Manufacturing Process with Metal Matrix Nano-Composites Professor Diana Lados has received a 3-year $423,783 NSF award for a proposal entitled “A Novel Method for Manufacturing Ceramic-Reinforced Metal Matrix Nano-Composites Using Liquid Metal Processing.” The applications of the outcomes of this research include means for obtaining higher energy efficiencies in the transportation sector through vehicle weight reduction. This award supports fundamental and applied research aimed at the development of a novel method for manufacturing nanoceramic reinforced metal matrix composites using liquid metal processing, where the ceramic reinforcement is created in-situ, within the molten metal. The early stage work in this area by Professor Lados was recognized in 2011 with the WPI’s Kalenian Innovation Award and Prize. Diana Lados Honored by SAE International and The Minerals, Metals, and Materials Society Lados, left, receives the Brimacombe Medal from TMS president Elizabeth Holm Diana Lados, associate professor of mechanical engineering at Worcester Polytechnic Institute (WPI) and founding director of the university's Integrative Materials Design Center (iMdc), recently received two major career achievement awards from leading engineering societies. At its annual congress in Detroit, SAE International, a global association of more than 138,000 engineers and related technical experts in the automotive, aerospace, and commercial vehicle industries, presented Lados with the 2014 Ralph R. Teetor Educational Award "in recognition of significant contributions to teaching, research, and student development." The award citation also noted the value these contributions bring to the mobility sector by successfully linking students and WPI to the transportation industries. Earlier, the Minerals, Metals and Materials Society (TMS) awarded her the Brimacombe Medal at its annual meeting and exhibition in San Diego, CA. The award, presented to mid-career professionals, recognizes sustained excellence and achievement in business, technology, education, public policy, or science related to materials science and engineering. Lados was honored for developing and implementing a new integrative design paradigm in materials science and engineering research, education, and application, and for impactful service to TMS. "It is a great honor to receive the Brimacombe Medal," Lados said. "I look forward to continuing to play an active role in TMS and to contributing to the society through my research in materials design integration, by organizing symposia and participating in committees, and by supporting new activities that will ensure a great future for the organization." Lados and the iMdc’s Research on Lightweight Metals and Additive Manufacturing Featured in Modern Metals Magazine and JOM In 2014, Lados’s research and developments were also featured in Modern Metals magazine in an editorial automotive report entitled “Not The Same Old Sedan.” The article looked at significant advances, requirements, and developing trends in the design and use of lightweight materials in modern vehicles to improve performance, safety, and fuel efficiency goals. Read more: http://www.modernmetals.com/item/11894-not-the-same-old-sedan.html A review by Lados and the iMdc team of additive manufacturing technology, including their history, operating principles and applications, sustainability considerations, and future trends, was published in the May issue of JOM in an article titled “Additive Manufacturing: Making Imagination the Major Limitation.” (Authors: Yuwei Zhai, Diana Lados, and Jane LaGoy). Read more: http://link.springer.com/article/10.1007%2Fs11837-014-0886-2 6 On a musical note… Modern Materials in Harmonicas Professor Charles L. Innis, Mechanical Engineering, WPI (Presented as part of the Music Materials Module for the 2014 WPI Materials Experience) One of the ways we can see modern materials applied to traditional musical instruments is by looking at how harmonica construction has changed in the last few decades. Both of the harmonicas used as examples were made by Hohner of Germany, a company who has retained a high reputation since the 1870s. They are the traditional Marine Band type. A traditionally constructed harmonica is a sandwich. The central core is a wooden block with 10 channels machined in it which direct air through reeds in the reed plates which form the next layer of the sandwich. One set of reeds vibrates when air is sucked through it by the player, the other set vibrates when the player blows air through them. Reed plates and reeds are rolled bronze or brass; holes for the reeds are machined in the plates and the reeds are riveted to the plates, which are nailed to the core. The outer layers of the sandwich are formed, chrome plated brass covers. The covers form a smooth, rolled surface for the player’s lips to seal against and an opening on the other side for the sound to emerge, plus provide protection for the reeds on the outer surface of the reed plate. The sandwich is fastened together with four brass wood screws driven into the wooden block, two at each end. Some skill is required at assembly, as there appear to be no means of locating the layers of the sandwich in two dimensions. A modern version of the harmonica, which is made in China, replaces the wooden block and the outer covers with molded plastic parts, and the four wood screws with two through bolts. By analyzing the modern version, we can see how the German engineers utilized new materials to replace the old while maintaining the traditional company quality. Sound quality appears to be the same for both new and old. The core: The traditional wooden block required machining, first to form the block, then to create the channels. Extensive use of the harmonica results in moisture buildup from the breath of the player; failure to knock the moisture out can result in swelling of the wood. Once the wood dries out, it is liable to crack, thus allowing air to flow in more than the desired channel and produce discord. Molding the core in plastic requires an expensive mold, but produces the core with all channels in one step, plus trimming. The plastic will not absorb moisture or crack on drying. There are hollows molded in the plastic to save material. The reed plates and reeds: These are the heart of the instrument and do not appear to have been changed, at least superficially. They are attached to the core by screws from one plate to the other instead of the nails used in the traditional instrument. Lips on the plastic core position the reed plates; presumably fixtures are used in assembly of the traditional instrument. The covers: The traditional instrument uses two covers of rolled, stamped brass which is chrome plated, then stamped with maker’s and award information before being formed. The modern instrument uses two covers molded from plastic. An expensive mold is required, but produces a cover which only requires trimming of the flash. Producing a traditional brass cover requires production of the rolled brass plate, stamping and forming it, then applying chrome plating. To use a nontechnical term, chrome plating is a nasty process, involving serious environmental and health hazards even when used with care. Producing the shiny surface of the traditional covers requires skill and attention to detail. Assembly: The traditional harmonica appears to require external fixturing and some skill; no self-locating features are evident. Disassembly and reassembly would be difficult, as the wood screws which attach the covers are small and would allow few, if any, repetitions. The modern harmonica is self-fixturing, using molded lips on the core and molded holes for the two through bolts which attach the covers, one at each end. It appears that the instrument can be easily assembled and disassembled a number of times without affecting its performance. Little skill appears to be required in assembly, as evidenced by the experience of the instructor of the class – a partially disassembled modern instrument and an assembled traditional instrument are passed around in each class for examination. The modern instrument does not appear to have suffered from the 24 classes to which it has been exposed. The construction of the modern instrument allows it to be cleaned, should it be dropped in a sand box or some similar environment. Packaging: The traditional instrument is offered for sale in a cardboard or molded plastic box, which serves as a case. The modern instrument is inserted in a clear plastic sleeve with an applied paper label giving maker, cautions, and production information. Conclusion: The modern instrument has benefited highly from applying modern materials and techniques where appropriate, while retaining traditional materials for the performing heart. Cost reduction is significant; the author remembers paying $5 for a similar Hohner Marine Band harmonica in the 1960s, while the modern instrument cost $3 in 2014. 7 8 WPI Student News WPI Material Science and Engineering: Manufacturing the Future Aaron Birt, President of WPI Chapter of Material Advantage, 2014 Chet Inman Award Winner With school winding back up on the hill at WPI again, it’s time to shift the focus away from the sunny beaches, summer reading, and of course “critical” research back towards the courses and applied learning that makes WPI famous. This year, however, some in the Material Science Department at WPI are taking a slightly different direction. In addition to the normal rigmarole of theoretical based courses, the Material Advantage Club at WPI is hoping to implement a series of Friday morning lectures dedicated to the cause of “practical material science.” These courses will include information sessions on polishing, microscopy, hardness testing, planning a research project, and other topics that students at the graduate and undergraduate level might find helpful. If you have an experience or lecture that you think would benefit the students at WPI, contact Aaron Birt (ambirt@wpi.edu) for more information. To enhance the learning of those undergraduate students that have expressed interest in Material Science, the club is also planning to institute an internship program for undergraduate students to become involved in graduate level research early on in their student careers. Qualified undergraduate students will be connected with graduate students who will coach the undergraduates through a research project that is related to their own graduate level research. The goal is to use this internship program as a substitute learning experience for those that might wish to make material science a future career path. Professor Diran Apelian recently proposed another solution to the practical education of WPI’s graduate and undergraduate students. With so much hype placed these days on additive manufacturing and the “maker” community, he decided that it is time for WPI to have its own community of makers that can reach back to the roots of material science and “making.” This means getting students at all levels involved with time-honored trades like blacksmithing and glassblowing to help them understand the modern laws of material science that enable us to “make” with incredible modern processes like additive manufacturing. But of course, WPI Material Science and Engineering won’t be all fun and games this year. WPI and the Metal Processing Institute in particular will be one of four academic institutions working on a $148 million light metals initiative sponsored by the White House and will be leading research in the area of casting. An additional $7.4 million award was given to WPI by the U.S. Army Research Laboratory to continue its work in nanomaterials and to begin an initiative to investigate alternative solutions to the United States’ rare earth dilemma. Focus areas for this award will be in cold spray modeling, nanostructured materials and alternatives to rare earth alloying elements. So the next time that you are on the hill, be sure to come visit Washburn Shops and see how the Material Science department at WPI is changing the world by developing stronger aluminum alloys, repairing defective military rotorcraft, creating the next generation of cathode batteries, recycling your aluminum scrap, or even designing the next generation of solar cells. Baillie McNally’s “Starry Night” micrograph of the microstructure of a Cold Spray Aluminum Alloy, which was viewed with a light microscope and polarized light, won Second Place in the category of Artistic Microscopy Color Only. The winners of the contest will appear in a future issue of Advanced Materials Processes and Slip Lines ASM Historical Landmark – Wyman Gordon ASM Historical Landmark Award for PCC Wyman Gordon, Grafton, MA From the Iron Bridge to the Statue of Liberty, ASM Historical Landmarks identify the many sites and events that have played a prominent part in the discovery, development and growth of metals and metalworking. In 1987, the scope of ASM Historical Landmarks was broadened to include all engineered materials. In 2013, the 100th Anniversary of ASM and of the Forging Industry Association, provided the perfect opportunity to recognize ”The World’s Historic, Heavy, Hydraulic Closed-Die Forging Presses”. These giant presses allowed quantum changes in the approach to modern aircraft design by producing large, forged, monolithic structures. The Wyman-Gordon 50,000 ton press (see photo below) redefined what was possible with respect to the production of large closed die forgings and the thermo-mechanical working of difficult to process aerospace aluminum and titanium alloys, steels and nickel-base superalloys. The capability of the press was a massive step forward relative to anything else existing at the time. The initial focus was on forging of aluminum alloys, but as melting technologies started to advance, and as the capabilities of the heavy presses came to be realized, the demand for large titanium alloy forgings for airframe applications and nickel-base superalloy forgings for jet engine components quickly grew. The important materials significance was the new ability to produce much larger components for aircraft that met all of the microstructural and mechanical property requirements, as opposed to having to produce smaller components that needed to be joined together. The elimination of many joints and fasteners ultimately led to lighter and stronger aircraft construction and enabled growth in aircraft size and performance. Famous examples of this include the Ti-6Al-4V main landing gear support beam forgings for the Boeing 747 and the Ti-6Al-4V (or Ti-6Al-4V ELI) bulkhead forgings for military aircraft such as the F-18, F-22 and now the F35. The largest nickel-base superalloy closed die forgings for jet engines using alloys like IN-718 and the huge forgings for land-base gas turbines using alloy IN-706 are today successfully and economically produced on the Wyman-Gordon 50,000 ton and 35,000 ton presses. Design and construction of the Wyman-Gordon 35,000 ton and 50,000 ton presses, as part of the Air Force Heavy Press Program, was carried out by the Loewy Construction Company. The 35,000 ton press went into operation in February 1955. The 50,000 ton press: began operating in October 1955. On September 18, 2014, ASM will hold a dedication ceremony at PCC Wyman Gordon at which Thom Pessak, Managing Director of ASM International, will present the ASM Historic Landmark Plaque. 9 10 Pollution-Eating Buildings Italian architectural firm, Nemesi & Partners, has revealed its award winning plans to clad Palazzo Italia in Milan with a smog-filtering facade as part of the Milan Expo 2015. The unique pavilion will be made from a special air-purifying cement created by Italcementi and will stretch over 9,000 square meters (96, 875 sq ft), requiring an estimated 2,000 tonnes (2,204 tons) of cement to accomplish the feat. "The entire outdoor surface and part of the interiors will consist of i-active biodynamic cement panels," says Italcementi. "In direct sunlight, the active principle contained in the material 'captures' certain pollutants present in the air and converts them into inert salts, helping to purify the atmosphere from smog." Some 80 percent of this air-purifying cement is made from recycled materials, such as scraps from Carrara marble. The Palazzo Italia will also be fitted with a photovoltaic glass rooftop to generate solar energy during the day. Turning to the unique architectural design of the facade, Nemesi & Partners wanted the building to act like a kind of urban jungle, not only aesthetically but by also mimicking the role of trees in city landscapes – which naturally help purify the air. Inspired by nature, the final design resembles large extended tree branches which wrap themselves around the iconic building. "The overall concept of the architectural design of the Italian Pavilion is that of an urban forest in which the building, through its skin and its volumetric arrangement, takes on the features of an architectural landscape," says Nemesi & Partners. "The branching pattern of the external cladding of Palazzo Italia coherently interprets the theme of the tree of life, inserting it in the form of a petrified forest." Palazzo Italia will be a central feature of the Milan Expo 2015 and, according to city plans, the cement facade is set to become a permanent feature, remaining long after the Expo has ended. Self-Cleaning Roof! http://www.innovationfund.rs/portfolio/self-cleaning-roof/ While the world’s eminent researchers are making huge efforts to create sustainable constructional materials, group of professors from the Faculty of Technology in Novi Sad, Serbia, has developed a completely innovative self-cleaning clay roofing tiles. This extraordinary self-cleaning ability of advanced and innovative clay roofing tiles comes from photo-catalytic activity of the TiO2 layer and its super-hydrophilic surface. The formation of layers of dust, soot and other inorganic and organic substances on the surfaces of tiles and the facades, as well as the effect of exhaust gases and microorganisms, can have many negative implications in deteriorating the initial characteristics of building materials and changing the esthetics of their surface. Applying active TiO2 to the surfaces of building materials and exposing them to sunlight creates antibacterial and anticorrosive effects along with the reduction of organic and inorganic compounds. After the photo-catalytic reaction, any dirt is easily removed from the treated area because it becomes super-hydrophilic. This means that it forms a film of water that interferes with the bonding contaminants. Thanks to the hydrophilic surfaces of self-cleaning materials, dirt is removed with the first rain or washing. There is no need for frequent cleaning of facades and streets, especially in big cities where the pollution level is higher. The look and mechanical characteristics of these clay roofing tiles do not differ much from the traditional tiles. An added value of this project is the fact that the tiles were produced using waste heat. In the world, there are a few companies producing self-cleaning materials. A few years ago the first self-cleaning roof tiles with hydrophobic surfaces (lotus effect) were placed on the market by the German company Erlus. The first pieces of “smart” tile for project testing purposes were produced in the plant factory “Polet” in Novi Bečej, Serbia, a member of Nexe group. The plans for continuous production of this modern and advanced product are now under way. Contact Us We hope that you enjoyed this issue of our newsletter. Please feel free to contact us at asmcmc@asm-ma.org 11