LEADER 00000cam a2200589 i 4500 
003    OCoLC 
005    20240129213017.0 
006    m     o  d         
007    cr cnu---unuuu 
008    221219t20232023njua    ob    001 0 eng   
010      2022057613 
020    9781119790860|qelectronic book 
020    1119790867|qelectronic book 
020    9781119790846|qelectronic book 
020    1119790840|qelectronic book 
020    1119790859|qelectronic book 
020    9781119790853|q(electronic bk.) 
020    |qhardcover 
024 7  10.1002/9781119790860|2doi 
029 1  AU@|b000074405708 
035    (OCoLC)1357020461 
037    9781119790730|bO'Reilly Media 
040    DLC|beng|erda|cDLC|dOCLCF|dYDX|dDG1|dORMDA|dN$T|dOCLCQ
       |dOCLCO 
042    pcc 
049    INap 
082 00 669/.82 
082 00 669/.82|223/eng/20230103 
099    |h[O'Reilly electronic resource] 
100 1  Sarkar, Debasish,|d1972-|eauthor. 
245 10 Fundamental design of steelmaking refractories /|cDebasish
       Sarkar.|h[O'Reilly electronic resource] 
264  1 Hoboken, NJ :|bJohn Wiley & Sons, Inc.,|c2023. 
264  4 |c©2023 
300    1 online resource (xix, 507 pages) :|billustrations (some 
       color) 
336    text|btxt|2rdacontent 
337    computer|bc|2rdamedia 
338    online resource|bcr|2rdacarrier 
504    Includes bibliographical references and index. 
505 0  Frontmatter -- Heat and Mass Transfer -- Equilibrium and 
       Nonequilibrium Phases -- Packing, Stress, and Defects in 
       Compaction -- Degree of Ceramic Bonding -- Thermal and 
       Mechanical Behavior -- High Temperature Refractory 
       Corrosion -- Operation and Refractories for Primary Steel 
       -- Operation and Refractories for Secondary Steelmaking --
       Precast and Purging System -- Refractories for Flow 
       Control -- Refractories for Continuous Casting -- 
       Premature Refractory Life by Other Parameters -- Index 
520    "The first part of the book accentuates the valuable 
       basics of 'Heat and Mass Transfer', 'Equilibrium and Non-
       equilibrium phases', 'Packing and Stress in Compaction', 
       'Degree of Ceramic Bonding', 'Thermal and Mechanical 
       Behavior', and 'High Temperature Corrosion' including 
       relevant finite element analysis in the perception of 
       composition design, manufacturing, and failure mechanism 
       of steelmaking refractories. While considering the 
       steelmaking refractories, a detailed 'Refractories for 
       Primary Steel Making', 'Refractories for Secondary Steel 
       Making', 'Refractories for Precast and Purging System', 
       'Refractories for Flow Control', 'Refractories for 
       Continuous Casting', and 'Premature Refractory Life by 
       Other Parameters', are essential to acme. These issues 
       have been discussed in the second half of the book to 
       fulfill the academic demand of undergraduate, postgraduate,
       and research scholars of ceramic engineering, 
       metallurgical engineering, and mechanical engineering 
       outlets who want to nurture in the refractory and steel 
       sectors. The description of such cumulative basic 
       knowledge, collective shop floor data, and relevant 
       failure analysis criteria makes sense and eventually 
       stimulates the awareness of how to grasp and analyze a 
       particular class of refractory for steelmaking. Refractory
       production, as fighting fit as their consumption, includes
       a certain degree of heat and mass transfer. Preliminary 
       from the thermodynamics, heat and mass transfer mechanisms
       are being described, and eventually, an analogy is drawn 
       in Chapter 1. In-situ phase formation during manufacturing
       and transformation in the presence of impurities are 
       common phenomena in refractory, and thus fundamentals of 
       binary and ternary equilibrium phases and non-equilibrium 
       phases are described in Chapter 2. Optimum compaction and 
       load are a prerequisite to press organic-bonded 
       refractories. A low load regime results in low green 
       density, whether high load beyond critical stress 
       consequences spring back and expedite lamination that 
       eventually produces defect and early stage failure during 
       the maneuver. Such phenomena are deliberated in Chapter 3.
       Industrial-scale production demands a uniform temperature 
       distribution throughout the kiln to form adequate ceramic 
       bonding or sintering of compact mass otherwise results in 
       premature refractory failure. In this regard, Chapter 4 
       describes the initial and final stages of sintering, 
       densification, grain growth, and their shape in the 
       matrix. Even with refractory processing failure, 
       meticulous thermal and mechanical stress cracking, severe 
       wear aggravated by abrasion, and corrosion are unavoidable
       in refractory practice and applications. In these concerns,
       Chapter 5 highlights the thermal and mechanical behavior, 
       and Chapter 6 underscores the high temperature corrosion 
       mechanism with a relevant model"--|cProvided by publisher.
588    Description based on online resource; title from digital 
       title page (viewed on May 17, 2023). 
590    O'Reilly|bO'Reilly Online Learning: Academic/Public 
       Library Edition 
650  0 Refractory materials. 
650  0 Steel|xMetallurgy. 
650  6 Matériaux réfractaires. 
650  6 Acier|xMétallurgie. 
650  7 Refractory materials|2fast 
650  7 Steel|xMetallurgy|2fast 
776 08 |iPrint version:|aSarkar, Debasish, 1972-|tFundamental 
       design of steelmaking refractories|dHoboken, NJ : JW-Wiley,
       2023|z9781119790730|w(DLC)  2022057612 
856 40 |uhttps://ezproxy.naperville-lib.org/login?url=https://
       learning.oreilly.com/library/view/~/9781119790730/?ar
       |zAvailable on O'Reilly for Public Libraries 
938    YBP Library Services|bYANK|n20216525 
938    EBSCOhost|bEBSC|n3610534 
994    92|bJFN