DOCSLIB.ORG

Float Glass Production

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Float Glass Production FLOAT GLASS PRODUCTION Nel Hydrogen 124 Glass-Technology International 5/2020 nel hydrogen art GTI5.indd 124 12/10/20 12:07 Nel’s Alkaline Water Electrolysers (Hydrogen Generators) have been in use for decades at float glass manufacturing facilities Nel is a global, dedicated hydrogen company, delivering optimal solutions to produce, store and distribute hydrogen from renewable energy. Since its foundation in 1927, Nel has a history of development and continual improvement of hydrogen plants covering the entire value chain, from hydrogen production technologies to the manufacturing of hydrogen fuelling stations, providing all fuel cell electric vehicles with the same fast fuelling and long range as conventional vehicles today. Raymond Schmid - VP Sales and Marketing EMEA-Oceania ON-SITE TIN Nel Hydrogen irst developed by Sir tomotive windshields and Alistair Pilkington in more. If you see a clear or BATH F 1952, the float glass tinted flat piece of glass, it process creates a special- was most likely manufac- ised type of flat glass with tured using the float glass ATMOSPHERE an extremely smooth, uni- process. form structure and supe- rior optical qualities. Over THE PRODUCTION the past 60 years, this OF FLOAT GLASS GENERATION method has not lost its rel- Float glass is produced on evance. Today float glass a continuous production is everywhere. It is used line. First, raw materials IMPROVES to construct windows and such as sand, dolomite, doors, the glass ‘skins’ of limestone, carbonate and modern skyscrapers, ta- sodium sulfate, as well bles, shelving and display as scrap glass are heated FLOAT GLASS cases, solar panels, plasma, to extreme temperatures PRODUCTION LCD and LED screens, au- (1,500°C/2,800°F) to form Glass-Technology International 5/2020 125 nel hydrogen art GTI5.indd 125 12/10/20 12:07 FLOAT GLASS PRODUCTION As stand-alone units or working together in a network for greater output, Nel PEM Water Electrolysers offer the safest, most advanced technology for producing high purity hydrogen for float glass atmospheres molten glass. This glassy template for the glass to the most important tasks at to stop this oxidation from liquid then moves into the distribute over and then this stage is to prevent the occurring and to avoid tin bath chamber, which harden into high-quality interaction of oxygen with a negative impact on the has a controlled atmos- flat glass. the tin. glass, a protective atmos- phere, where it is poured Tin is a metal that does The oxidation of tin in- phere is used in the tin onto the surface of molten not react with glass, but troduces flaws in the tin’s bath chamber. This atmos- tin. As the molten glass is the forming basis for a structure, which in turn phere usually consists of floats on top of this tin flat surface of glass with- will create flaws in the sur- 90 per cent nitrogen (N2) bath, the tin acts as a level out optical defects. One of face of the glass. In order and 10 per cent hydrogen 126 Glass-Technology International 5/2020 nel hydrogen art GTI5.indd 126 12/10/20 12:07 (H2). While the nitrogen tion purposes have used a high risk of explosion. and creates carbon dioxide remains non-reactive in the compressed gas or liquid Given the high volume of (CO2) emissions, a very process, the hydrogen will forms of nitrogen and hy- nitrogen required in the damaging greenhouse gas. react with any oxygen pre- drogen, which are supplied float glass process, the lo- Depending on the method sent, preventing any oxida- by pipeline from a nearby gistics of transporting the used, for every ton of H2 tion of the tin. producer, or by trucks in nitrogen to the glass plant produced, 11 to 19 tons of tanks or tube trailers. How- can also present a problem. CO2 is released. DETERMINING ever, this is not without its Any disruption to the sup- The main driver for CG WHICH TECHNOLOGY problems. ply chain, whether from a and SMR applications is IS BEST – USING strike, natural disaster or the low specific cost of THE RIGHT GAS Nitrogen global pandemic can cut hydrogen produced. How- In order to determine Nitrogen is typically pro- off the flow of nitrogen to ever, the disadvantages are which technology is the duced with air separation the plant causing a shut- the high cost of equipment, best to produce protective units using pressure swing down of production. To costly and lengthy mainte- atmospheres, there are sev- absorption technologies. help keep glass production nance, and the presence of eral factors to considered: This method provides the operating at peak efficiency impurities in the hydrogen, • High purity require- highest purity of nitrogen and safety, plant managers which requires additional ments for process gases available, and can be cooled should consider installing purification equipment. • Large volume of gas and compressed into liq- air separation units on-site Add to that the changing demand (average: 800 uid form and stored cryo- to replace, or at least sup- attitudes and legislation Nm3/h nitrogen and 90 genic containers. However, plement delivered nitrogen. around the world on green- Nm3/h hydrogen) whether as a compressed house gas emissions, de- • Sourcing gas supply gas or liquid, nitrogen is a Hydrogen carbonization of industries • Environmental impact dangerous element to store. Most hydrogen is produced and the expense of carbon of generating the gasses If it escapes into an en- via coal gasification (CG) capture equipment now be- Traditionally, industries closed space, there is a high or steam methane reform- ing required, CG and SMR that require high volumes risk of asphyxiation, or if ing (SMR), which uses are starting to fall out of of these gasses for produc- pressure builds up there is fossil fuels as the feed stock favour. In addition, liquid Nel Water Electrolysers (Hydrogen Generators) for float glass manufacturing Glass-Technology International 5/2020 127 nel hydrogen art GTI5.indd 127 12/10/20 12:07 FLOAT GLASS PRODUCTION hydrogen is highly explo- legislation. By producing and the differential pres- constantly monitor the op- sive which means it must the hydrogen on-site as sure between the hydro- eration process adhering be handled very care- needed, the plants can also gen and oxygen streams to several dozens of safety fully, and requires a large eliminate the safety and ensures that there is no parameters. storage area and special storage problems of deliv- mixing of the gasses. This As float glass facility man- permitting. ered hydrogen. mechanism of the Proton agers contemplate changes Hydrogen production PEM system has brought or additions to their tin through traditional alka- WATER ELECTROLYSIS water electrolysis to a new bath atmosphere supplies, line water electrolysis is a – THE OPTIMAL level of safety. The high it should be noted that well-known technology to CHOICE purity of hydrogen is due to each project requires a the glass market. In this Given the importance of using pure DI water as the detailed technical and eco- process, the electrolyser hydrogen purity for the only raw material. Hydro- nomic analysis, taking into uses a liquid alkaline elec- float glass process, all the gen purification consists account specific plant re- trolyte (NaOH or KOH) features of CG and SMR of drying the hydrogen quirements. Nel Hydrogen to facilitate the electrolysis. operations, and the same through two internally in- produces hydrogen gen- While installation of an al- logistic problems for de- stalled pressure swing ab- erators, both alkaline and kaline system may require livered hydrogen as for sorption tubes. There is Proton PEM technologies, RTN and other permits as delivered nitrogen, the pro- no need to have additional and can match the needs well as additional inspec- cess of water electrolysis is purification and treatment of any float glass opera- tions and special insurance the optimal choice for the equipment. The standard tion. Nel provides turnkey due to the caustic nature float glass process. Today purity of hydrogen is guar- solutions… the implemen- of the alkali, the system is the safest, most advanced anteed at a level of not less tation of all stages includ- extremely reliable and ef- technology to produce the than 99.9995 per cent with ing production, delivery, ficient. Many float glass purest hydrogen is through a dew point of 72°C. commissioning, warranty plants have been using this Proton Exchange Mem- With the absence of a and post-warranty service technology for decades to brane (PEM) water elec- liquid alkaline tank and throughout the life of the produce the hydrogen they trolysis. This process uses mechanical high-pressure equipment. require for their tin bath a caustic free solid polymer compression on the hydro- atmospheres. Because the electrolyte as the catalyst to gen line, PEM systems are hydrogen produced by wa- crack the water molecule more compact than their ter electrolysis is generated (H2O) into hydrogen (H2) Alkaline counterparts. A by cracking water mol- and oxygen (O2). more important benefit ® ecules (H2O) into hydro- In a Nel Proton PEM that comes with the ab- gen (H2) and oxygen(O2) electrolyser, deionized wa- sence of alkali in the PEM using only electricity and ter and electricity are fed systems in the lack of need an electrolyte, no green- into the cell stack. Here, for ‘hazardous production Nel Hydrogenyg house gasses are produced. water splits at the anode facility’ signs, RTN and The only by-product is into electrons, protons other special permitting, oxygen. When hooked up and gaseous oxygen (O2) additional inspections and to a source of renewable at a pressure of 1.5 barg. special insurance. energy for the electricity, Protons then pass through Nel electrolysers oper- true green (zero carbon) the proton exchange mem- ate automatically and do hydrogen is produced.
Load more

Recommended publications
  • Quarterly Journal of the All India Glass Manufacturers' Federation
    Vol. 3 | No. 4 | January - March 2016 Quarterly Journal of The All India Glass Manufacturers’ Federation Bi-lingual www.aigmf.com Technical Articles Prof. (Dr.) A. K. Bandyopadhyay Prof. (Dr.) A Sustainable 50 for postage postage for 50 ` ASS ASS www.aigmf.com Building and Packaging material An Publication - GlASS Gl Gl 500 (within India) + + India) (within 500 ` ` Kanch | Vol. 3 | No. 4 | January-March 2016 2 Overseas: US$ 60 (including postage and bank charges) bank and postage (including 60 US$ Overseas: Order Print Copies: Print Order Price: Price: www.aigmf.com President SANJAY GANJOO Sr. Vice President ARUN KUMAR DUKKIPATI Vice President RAJ KUMAR MITTAL Hon. General Secretary BHARAT SOMANY Hon. Treasurer SANJAY AGARWAL Member Editorial Board A K Bandyopadhyay Quarterly Journal of THE ALL INDIA GLASS MANUFACTURERS’ FEDERATION Former Principal, Govt. College of Engineering & Ceramic Technology-GCECT, Kolkata DEVENDRA KUMAR Prof. & HOD, Dept. of Ceramic, Indian Institute of Technology (Banaras Hindu University) Vol. 3 | No. 4 | January-March 2016 K K SHARMA President, NIGMA and Plant Head, HNG Neemrana, Rajasthan MEMBER ASSOCIatIONS EASTERN INDIA GLASS MANUFACTURERS’ ASSOCIATION (EIGMA) Contents c/o La Opala RG Ltd. Chitrakoot, 10th Floor, 230 A, A.J.C. Bose Road From President's Desk 5 Kolkata - 700 020 President - Sushil Jhunjhunwala Glass as Vital Building Material for Smart / Solar Cities NORTHERN INDIA GLASS MANUFACTURERS’ ASSOCIATION (NIGMA) & c/o Hindustan National Glass & Industries Limited 6 Post Office - Bahadurgarh, Jhajjar, Haryana-124 507 Book Launch: “Glass - A Sustainable Building and Packaging President - KK Sharma Material” Vice President - Jimmy Tyagi Honorary General Secretary - NN Goyal Glass News 13 Secretary & Treasurer - JB Bhardwaj SOUTH INDIA GLASS MANUFACTURERS’ ASSOCIATION (SIGMA) Smart City and Glasses for Flat-Screen Products – Part II 21 c/o AGI Glasspac (An SBU of HSIL Ltd.) Glass Factory Road, Off.
    [Show full text]
  • Float Glass Inspection and Measurement Phone: +1-651-730-4090 Fax: +1-651-730-1955 for Highest Quality and Optimized Yields
    Germany Phone: +49-89-85695-0 Fax: +49-89-85695-200 USA Float Glass Inspection and Measurement Phone: +1-651-730-4090 Fax: +1-651-730-1955 for Highest Quality and Optimized Yields Korea Phone: +82-2-527-1633 Fax: +82-2-527-1635 Taiwan Phone: +886-2-2920-7899 Fax: +886-2-2920-8198 Dr. Schenk’s production site Hong Kong Phone: +852-2425-1860 Fax: +852-2425-6775 China-Beijing Dr. Schenk GmbH, established in 1985, is an innovative Phone: +86-10-6503-2159 high-tech company based near Munich, Germany. Fax: +86-10-6503-2161 Dr. Schenk develops, produces and markets optical surface inspection and measurement solutions for automated China-Shanghai quality assurance and production process monitoring. Phone: +86-21-5836-6700 The systems are a key success factor in the making and Fax: +86-21-5836-6701 converting of many materials, e.g. plastics, glass, metal, PV modules, wovens & nonwovens, and the semiconduc- tor industry. Throughout the world Dr. Schenk’s 220 employees con- For further regional sales & tinue to set new standards for the inspection of surfaces. service representatives please refer Over 10,000 m² of modern production and testing facili- to www.drschenk.com ties are available to research, development and production to apply cutting-edge optics and electronics to customer applications. The company’s objective is complete customer satisfaction. This is achieved through innovative and practical solutions that can be implemented into new and existing production lines. Local sales and service facilities around the world ensure fast support, technical service, training and consult- ing at any phase of a project.
    [Show full text]
  • ENABLING WONDERS. INSPIRING AWE. AIS Architectural Product Profile
    ENABLING WONDERS. INSPIRING AWE. AIS Architectural Product Profile 1 FROM ART TO ARCHITECTURE Architecture is an emotional experience that begins in the mind of the architect. It starts from a vision that transforms into an art. Just like any artist, the architect gets to play with various materials and ideas. Glass is the latest material that is allowing architects to interpret space in a whole new way, inspire creative designs, and create structures that reflect beauty. AIS has the knowledge, expertise, and an unmatched array of products to bring an artistic idea from a vision to a masterpiece. 2 Cummins, Pune 3 ENABLING A FUTURE THAT SEES MORE AIS is India’s leading integrated glass company. Being a leader, AIS delivers top-of-the-line products and solutions through three Strategic Business Units (SBUs) of Automotive Glass, Architectural Glass and Consumer Glass. We use our glass product portfolio – which is the biggest in the country – to meet functional needs in an aesthetic and contemporary manner. With products that provide next-generation solutions, AIS brings new ideas to life – enabling an age of ‘green buildings’ and the dawn of a truly sustainable future. Taking the versatility of glass to the next level, AIS today has unmatched glass processing capabilities, including the processing of special glass products, that enables us to meet your every need, and fulfil every requirement. And help you realise your dream house in glass. 4 ARCHITECTURAL GLASS Architectural Glass, or float glass, is manufactured by floating the molten glass on a bed of molten metal, typically tin. This method gives the glass product uniform thickness and a very flat surface.
    [Show full text]
  • Glass Shaping
    MIT 3.071 Amorphous Materials 6: Glass Shaping Juejun (JJ) Hu 1 After-class reading list Fundamentals of Inorganic Glasses Ch. 20 Introduction to Glass Science and Technology Ch. 13 2 Image @ MIT. All rights reserved. This content is excluded from our Creative Commons license. For more information, see http://ocw.mit.edu/help/faq-fair-use/. “Viscosity makes things happen essentially in slow motion. If you are trying to melt a crystalline solid (like ice or an aluminum oxide ceramic), as soon as you reach the melting point, a drop of liquid forms and falls away from the melting surface. Glass, on the other hand, … gradually transforms from a hard solid to a slowly softening liquid. This soft liquid gradually stiffens as it cools (because of its increasing viscosity), allowing glass blower time to shape and manipulate the glass.” http://madsci.org/posts/archives/2007-09/1188944613.Ph.r.html 3 Viscosity reference points Working range PGM Glass blowing Lehr annealing Fiber drawing Float glass Pitch: 2.3 × 108 h 101 103 106.6 1012 1013.5 (Pa·s) Melting Working Softening Annealing Straining point point point point (Tg) point 4 Basic properties of common silicate glasses Soda-lime Borosilicate Fused silica CTE (ppm/°C) 9.2 3.2 0.5 Working point 1005 1252 N/A (°C) Softening point 696 821 1650 (°C) Annealing point 510 560 1140 (°C) Strain point (°C) 475 510 1070 5 Flat glass manufacturing: float glass process Forming of a continuous ribbon of glass using a molten tin bath Melting and refining (homogenization and bubble removal) Float bath: glass thickness controlled by flow speed Annealing: stress release Inspection, cutting and shipping 1 2.5 12 15 10 Pa·s 10 Pa·s 10 Pa·s > 10 Pa·s © H.S.
    [Show full text]
  • Precision Sensors & Applications Glass Industry
    Sensors & Applications Glass Industry More Precision Sensors and measuring systems confocalDT 2421 / 2422 Confocal chromatic sensors for for glass production distance and thickness measurements Modern glass production is increasin- One-sided thickness measurement of gly determined by maximum efficiency. transparent materials Therefore, rapid access to fundamental Synchronous 2-channel measurement process variables is required in order to with max. measuring rate ensure fast control of the process. With Best price/performance ratio in its class products such as container glass, flat glass or special glasses, tight manufac- turing tolerances must be adhered to while maintaining the shortest possible cycle times. colorCONTROL ACS Sensors for color measurement of transparent materials Due to the high degree of integration as Ideal for integration into processing lines well as the high accuracy and measure- due to high measuring rates ment speed, sensors from Micro-Epsilon are used in the glass industry for different High accuracy measurement tasks: robust eddy current Robust and suitable for industrial applications sensors are integrated into machines in order to detect machine movements while optical sensors monitor glass products in processing lines. Typical measured para- meters include displacement, position, thermoIMAGER / thermoMETER thickness, color and temperature. Thermal imaging cameras and infrared pyrometers for non-contact temperature measurement Fast and precise temperature measurement Real-time process monitoring and system control Compact design & extensive range of interfaces optoNCDT 1420 Compact laser triangulation displacement sensor for high speed, precision measurements Non-contact displacement and distance measurements with large measuring ranges from 10mm to 500mm High accuracy High measuring rate for dynamic measurements Compact design and easy to install Flat glass Temperature measurement of float glass After the tin bath, flat glass has a temperature of approx.
    [Show full text]
  • Brief History of the Flat Glass Patent
    World Patent Information 38 (2014) 50e56 Contents lists available at ScienceDirect World Patent Information journal homepage: www.elsevier.com/locate/worpatin Brief history of the flat glass patent e Sixty years of the float process Marcio Luis Ferreira Nascimento a,b a Vitreous Materials Lab, Institute of Humanities, Arts and Sciences, Federal University of Bahia, Rua Barão de Jeremoabo s/n, Idioms Center Pavilion (PAF IV), Ondina University Campus, 40170-115 Salvador, Bahia, Brazil b PROTEC/PEI e Postgraduate Program in Industrial Engineering, Department of Chemical Engineering, Polytechnic School, Federal University of Bahia, Rua Aristides Novis 2, Federação, 40210-630 Salvador, Bahia, Brazil article info abstract Article history: This paper deals with one of the single most important innovations made in Great Britain since World Available online 4 July 2014 War II. It is certainly one of the greatest process inventions of the twentieth century. The float process is one of the most widely used methods for flat glass manufacturing as it ensures security, high quality and Keywords: productivity. From a historical point this innovation was the beginning of a revolutionary change in the Glass mass production of flat glass for the building and automotive sectors. More specifically this innovation Flat eliminates the traditional operations of rolling, grinding and polishing the glass surface while creating a Float high quality and inexpensive flat glass product. The first patent was applied for on December 10th, 1953 Patent History by Pilkington and Bickerstaff. This paper presents a brief discussion from the 1960s in a historical Technology perspective about this amazing discovery and the main patents related to it.
    [Show full text]
  • Glass Needs for a Growing Photovoltaics Industry Keith Burrows1 and Vasilis Fthenakis1,2* 1Center for Life Cycle Analysis, Colum
    BNL-107755-2015-JA Glass Needs for a Growing Photovoltaics Industry Keith Burrows1 and Vasilis Fthenakis1,2* 1Center for Life Cycle Analysis, Columbia University, New York, NY 2Photovoltaics Environmental Research Center, Brookhaven National Lab, Upton, NY Abstract With the projected growth in photovoltaics, the demand for glass for the solar industry will far exceed the current supply, and thousands of new float-glass plants will have to be built to meet its needs over the next 20 years. Such expansion will provide an opportunity for the solar industry to obtain products better suited to their needs, such as low-iron glass and borosilicate glass at the lowest possible price. While there are no significant technological hurdles that would prevent the flat glass industry from meeting the solar industry’s projected needs, to do so will require advance planning and substantial investments. 1. Introduction / Background For any solar technology to succeed, it must scale up in a manner that is the least expensive without compromising quality. Not only must the solar-cell manufacturers scale up their own manufacturing processes, they must ensure that their suppliers will be able to meet their demand. The 2005 to 2008 shortage of silicon needed to manufacture crystalline silicon solar cells is an excellent example of the problems that can occur when a supplier lags behind the development of an industry [1,2]. Although this was a temporary issue, it raised the prices for these technologies, and provided a window of opportunity for thin-film applications to capture a bigger market share. Most photovoltaic modules use glass.
    [Show full text]
  • Understanding Float Glass Firing Schedules
    Understanding Float Glass Firing Schedules There is a lot of misunderstanding about firing Different Thickness schedules for float glass. Most of that confusion With art glass if you want a 6m thick project you must comes from the assumption firing schedules will be fuse 2 layers of glass together. With float glass you very similar to those used for art glass. That can instead just use 6mm thick glass. confusion is compounded by a lot of misinformation being distributed that perpetuates myths about float Different Viscosity glass. Float is much stiffer than art glass so is slower to soften and requires higher temperatures to produce We should first talk about how float glass is different the same effects as art glass. than art glass. Let’s start with the most common myth – the assumption you can use the same firing Tin Side schedules for float you use for art glass by just With art glass it makes no difference which side of changing the top performance temperature by a the glass faces up unless you’re using textured glass fixed amount. You can use the same firing and want to retain the texture. Float is smooth on schedules used for COE 96 glass for COE 90° by both sides but it can make a huge difference whether just firing to 20°F higher but claiming you can do the you fire it in your kiln air side up or tin side up. same with float glass is wrong. There is no fixed temperature difference that will work. Let’s compare Allowances the differences between COE 96 fusing glass and These variables make it more difficult to get reliably float.
    [Show full text]
  • REPORT Functional Glasses
    Functional Glasses: Properties and Applications for Energy and Information REPORT Functional Glasses: Properties and Applications for Energy and Information January 6 – 11, 2013 Siracusa, Sicily, Italy Klaus Bange MK Consulting GmbH, Germany Himanshu Jain Lehigh University Carlo G. Pantano The Pennsylvania State University Sponsored by NSF’s International Materials Institute for New Functionality in Glass www.lehigh.edu/imi 1 Functional Glasses: Properties and Applications for Energy and Information Outline 1. Introduction 2. Glasses in Energy Technology 2.1 Applications of Glass in Energy Technology 2.2 Glass Properties for Energy Applications 2.3 Energy Storage Technologies 2.4 Summary: Glass and Energy 3. Glasses in Information Technology 3.1 Application of Glass in Information Technology 3.2 Glass Properties for Information Applications 3.3 Summary: Information Technology 4. Glass Processing and Fabrication 4.1 Summary: Glass Processing and Fabrication 5. Influence of the surface on glass properties 5.1 Summary: Glass surface and Properties 6. Summary 7. References Acknowledgement Appendix 2 Functional Glasses: Properties and Applications for Energy and Information 1. Introduction “The International Interactive Conference on Functional Glasses: Properties and Applications for Energy & Information” took place on January 6-11, 2013 in Siracusa, Sicily. The organization and funding of this unique conference were the result of a multi- year effort by the “NSF’s International Materials Institute for New Functionality in Glass (IMI-NFG)” to bring together active glass researchers with the industries using or manufacturing glass for innovative new products. The meeting was organized unlike most regular or topical conferences in order to promote extensive discussion amongst academics, technologists and manufacturers: invited speakers only, defined discussion leaders, an industry panel, a detailed summary report and a roadmap outlining future needs and opportunities for glass in these technologies.
    [Show full text]
  • Fusing Fusing
    ® Artist Robert Wiener FusingFusing ToolsTools && AccessoriesAccessories ProductProduct CatalogCatalog www.dlartglass.com © 2019 D&L Art Glass Supply © 2019 D&L Art Glass Artist Nancy Bonig 303.449.8737 • 800.525.0940 Table of Contents About the Artwork Cover - Artist: Robert Wiener, DC Art Glass Series: Colorbar Murrine Series Title: Summer Salsa Size: 6" square (approx.) Website: www.dcartglass.com Photographer: Pete Duvall Table of Contents- Alice Benvie Gebhart Title: Distant Fog Size: 6 x 8" Website: www.alicegebhart.com Kilns ..........................................................................1-16 Tabletop Kilns .......................................................................................................... 1–3 120 Volt Kilns ............................................................................................................1-5 240 Volt Kilns ........................................................................................................ 6-12 Kiln Controllers at a Glance .....................................................................................13 Kiln Shelves .......................................................................................................... 14–15 Kiln Furniture and Accessories ................................................................................16 Kiln Working Supplies ....................................... 17-20 Primers & Shelf Paper ...............................................................................................17 Fiber Products & Release
    [Show full text]
  • A NEW TECHNIQUE in GLASS ART JOANNE MITCHELL a Thesis Su
    PRECISION AIR ENTRAPMENT THROUGH APPLIED DIGITAL AND KILN TECHNOLOGIES: A NEW TECHNIQUE IN GLASS ART JOANNE MITCHELL A thesis submitted in partial fulfilment of the requirements of the University of Sunderland for the degree of Doctor of Philosophy August 2015 Precision Air Entrapment through Applied Digital and Kiln Technologies: A New Technique in Glass Art Joanne Mitchell PhD 2015 1 Precision Air Entrapment through Applied Digital and Kiln Technologies: A New Technique in Glass Art Joanne Mitchell 2015 Abstract The motivation for the research was to expand on the creative possibilities of air bubbles in glass, through the application of digital and kiln technologies to formulate and control complex air entrapment, for new configurations in glass art. In comparison to glassblowing, air entrapment in kiln forming glass practice is under-developed and undocumented. This investigation has devised new, replicable techniques to position and manipulate air in kiln-formed glass, termed collectively as Kiln-controlled Precision Air Entrapment. As a result of the inquiry, complex assemblages of text and figurative imagery have been produced that allow the articulation of expressive ideas using air voids, which were not previously possible. The research establishes several new innovations for air-entrapment in glass, as well as forming a technical hypotheses and a practice-based methodology. The research focuses primarily on float glass and the application of CNC abrasive waterjet cutting technology; incorporating computer aided design and fabrication alongside more conventional glass-forming methods. The 3-axis CNC abrasive waterjet cutting process offers accuracy of cut and complexity of form and scale, across a flat plane of sheet glass.
    [Show full text]
  • Brochure Glass Technology
    GLASS PRODUCTION TECHNOLOGY throughLet us the be world your of glass guide Content 4 Enthusiasm starts with excitement. 8 Grenzebach and CNUD EFCO GFT offer a seamless glass engineering experience. 10 Flawless glass manufacturing starts here – in the hot end. 10 The tin bath – endless fascination 11 The annealing lehr for quality glass 12 Waste heat recovery – a green approach 13 Utilities and central power supply – an eco-friendly feed stock solution 6 Today, we speak from experience. 14 The cold end, destined for flexibility and reliability. 14 Seamless conveying 14 Dynamic cutting technology 16 Metrology – good data means better results 17 Stacking technology – good stacking means better glass 20 Glass coating technology for that functional and attractive finish. 20 Glass with added value 21 Future-proof lab coater 18 Coating technology. 21 Integrated control Or the feel-good factor. 22 Smart, connected and transparent processes all along the line. 22 Integrated production logistics 23 Staying on track with product traceability 26 SERICY. A data powerhouse. 28 Plant operation and control that's a breeze. 24 What will the future be like? 29 Intuitive user interfaces Be a part of the journey with our 29 Lower workloads, higher availability digitalization solution for tomorrow’s glass production. 32 WeService. Premium service – and that’s a promise. 34 Grenzebach service to exceed expectations. 30 We live Service. Partnership and service that go the extra mile. startsEnthusiasm with excitement. Glass lets us gaze way out onto the horizon or view the Experts from many disciplines push boundaries because At the same time, we also want to team up with you to ensure ties available today inspire us to help you make your business world and what it has in store under a microscope.
    [Show full text]