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COMPARISON OF STATISTICAL MIX-DESIGN PROPORTIONS OF HIGH STRENGTH SELF-COMPACTING CONCRETE

COMPARISON OF STATISTICAL MIX-DESIGN PROPORTIONS OF HIGH STRENGTH SELF-COMPACTING CONCRETE. Özlem AKALIN , Plustechno Bahar SENNAROĞLU, Marmara University. Outline. Objectives Need for optimization of HS-SCC Statistical mixture experimental design

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COMPARISON OF STATISTICAL MIX-DESIGN PROPORTIONS OF HIGH STRENGTH SELF-COMPACTING CONCRETE

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  1. COMPARISON OF STATISTICAL MIX-DESIGNPROPORTIONS OF HIGH STRENGTH SELF-COMPACTING CONCRETE Özlem AKALIN, Plustechno Bahar SENNAROĞLU, Marmara University

  2. Outline • Objectives • Need for optimization of HS-SCC • Statistical mixture experimental design • Comparison of SMD method results with Okamura’s Rule • Conclusion

  3. Objectives • Need for HS-SCC mixture proportioning • Statistical Mixture Experimental Design Method • Optimum proportions of HS-SCC (C100/115) concrete class using SMD method • Comparing the results obtained from SMD method with Okamura’s Rule

  4. HSC demand is increasing due to its technical and economical benefits • Concrete or composite column is more economical than building with a pure steel • Taking full advantage of increased compressive strength : • reducing amount of steel, reducing column size to increase usable floor space or allowing additional stories without detracting from lower floors

  5. The development of SCC was started in 1983 to find a solution for more durable concrete structures in Japan. Self Compacting Concrete

  6. Prof.Dr.Hajime Okamura Kochi University of Technology

  7. SCC is a special type of concrete that has a high resistance to segregation • Adequate compaction to pour concrete • Better concrete quality • Shorter construction period

  8. Concrete design is an optimization of mixture Concrete Classes (TS EN 206-1) C8/10 C12/15 C16/20 C20/25 C30/37 C35/45 C40/50 C45/55 C50/60 C55/67 C60/75 C70/85 C80/95 C90/105 C100/115 HSC

  9. HSC mixture proportioning * HSC mixture proportioning is a more critical process than the normal strength concrete. Many trial batches are required to generate data that enables the researcher to identify optimum mixture proportions. *ACI Manual of Concrete Practice,1997.

  10. Mixture Experiments The measured responseis assumed to depend only on the proportions of ingredientspresent in the mixture and not on the amount of mixture Experiment and you’ll see! (Cole Porter)

  11. Mixture Experiments • A q-components mixture in which represents the proportion of the i th component present in mixture, • The composition space of the q components takes the form of a regular dimensional simplex.

  12. Physical, theoretical, or economic considerations often impose additional constraints on individual components * Quenouille, M.H

  13. Mixture Experiments • The purpose of mixture experiments is to build an appropriate model relating the response(s) to components . • Most commonly used mixture model forms in fitting data are the second-degree polynomials introduced by (Scheffé,1958) of the form

  14. D-optimal Design for HS-SCC was used to mathematically model the influence of eight mixture parameters and their 2-way interactions on responses 8 mixture parameters Cement (c), Silica fume(sf), flyash(pfa),water(w),natural sand(n-s), crushed sand(c-s), aggregate(agg), chemical admixture(adm) Responses T50 slump flow time, Slump Flow, Compressive Strength, Appearance, RCP

  15. Constraints on Mixture Components (L/m3)

  16. D-optimal Design Mixtures Proportions (L/m3) …….46 mixtures

  17. Experimental Test Results ……46

  18. Analysis of mixture experiment requires • Developing regression model relating response variable to components • Use of model for prediction and optimization Second degree SchefféPolynomials are considered since observations indicate that the interaction terms are important

  19. Statistical Analyses Results

  20. Desirability Objective Function where n is the number of responses in the measure. The numerical optimization finds a point maximizes desirability function. In this study desired response parameters were defined as target, maximum or minimum by giving importance degree and response optimization suggested input variables by predicting responses and desirability are tabulated in table.

  21. Optimization Targets

  22. Optimization Solutions

  23. Comparison of results

  24. Comparison of Results

  25. Okamura’s Rules for SCC 1) The volume of cement and fine powder: 170 <Vc+Vf= 187 < 200 2) Water/(cement+fine powder) by volume: 0.85 <Vw/(Vc+Vf) = 0.96 < 1.20 3) Volume of coarse aggregate: VG ≤ 340 L/m3 Dmax≤ 20 4) Maximum size of coarse aggregate:

  26. Comparison of SMD results with Okamura’s Rules

  27. Conclusion • Statistical experimental design provides systematic approach for concrete design, • Mixture experiments give advantage to reach optimum proportions of concrete mixture components at a minimum cost, • Results of SMD for HS-SCC (C100/115) are confirmed with Okamura’s Rules for SCC.

  28. THANK YOU

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