5. References

[1] Standard Test Method for Slump of Hydraulic Cement Concrete, ASTM C143 −97, Vol. 04.02.

[2] E. P. Koehler and D. W. Fowler, Summary of Concrete Workability. Test Methods, ICAR Report 105.1, International Center for Aggregates Research, Austin, TX, August 2003.

[3] C. Ferraris and L. Brower, eds., Comparison of Concrete Rheometers: International Tests at LCPC (Nantes, France) in October 2000, NISTIR 6819, September 2001. (PDF Version)

[4] C. Ferraris and L. Brower, eds., Comparison of Concrete Rheometers: International Tests at MB (Cleveland OH, USA) in May 2003, National Institute of Standards and Technology NISTIR 7154, September 2004. (PDF Version)

[5] L. E. Brower and C. F. Ferraris, Comparison of Concrete Rheometers, Concrete International 25 (8), 41-47 (2003). (PDF Version)

[6] H. Beitzel, Efficiency of Concrete Mixers−Report on Assessment and Classification of Performance of Mixers, RILEM TC-150-ECM (1998).

[7] F. de Larrard, B. Cazacliu, D. Chopin, and E. Chateau, Production of SCC, 3rd International Symposium on Self Compacting Concrete, Reykjavik, Iceland, 17-20 August 2003.

[8] D. Chopin, Malaxage des bétons à hautes performances et des bétons auto-plaçants: Optimisation du temps de fabrication, Collection Études et Recherches des LPC − série Ouvrages d'art − nº 41, Issn 1161−028X, juin 2003.

[9] C. F. Ferraris and F. de Larrard, Modified Slump Test to Measure Rheological Parameters of Fresh Concrete, Cement, Concrete Aggregates 20 (2), 241-247 (1998).

[10] J. A. Daczko, AProposal for Measuring Rheology of Production Concrete, Concrete International 22 (5), 47-49 (2000).

[11] Y. Charonnat and H. Beitzel, RILEM TC 150 ECM: Efficiency of Concrete Mixers - Report: Efficiency of Concrete Mixers Towards Qualification of Mixers, Mater. Struct. (Suppl. 196) 30, 28-32 (1997).

[12] R. Helmuth, L. Hills, D. Whitting, and S. Bhattacharja, Abnormal Concrete Performance in the Presence of Admixtures, Portland Cement Association # 2006 (1995).

[13] E. P. Koehler, Development of a Portable Rheometer for Portland Cement Concrete, MS Thesis, The University of Texas at Austin, Austin, TX (2004).

[14] E. P. Koehler, D. W. Fowler, C. F. Ferraris, and S. Amziane, A New Portable Rheometer for Fresh Self-Consolidatinng Concrete, Proc. of session ACI 2005 (New York).

[15] H. A. Barnes and Q. D. Nguyen, Rotating Vane Rheometry − a Review, J. Non-Newtonian Fluid Mech. 98 (1), 1-14 (2001).

[16] A. W. Saak, H. M. Jennings, and S. P. Shah, The Influence of Wall Slip on Yield Stress and Viscoelastic Measurements of Cement Paste, Cement and Concrete Research 31 (2), 205-212.

[17] S. Amziane and C. F. Ferraris, Monitoring of Setting Evolution of Cementitious Materials by Measurements of Rheological Properties and Hydraulic Pressure Variations, submitted to Mater. Struct., RILEM (2005).

[18] R. J. Flatt, Towards a Prediction of Superplasticized Concrete Rheology, Mater. Struct./Mater. Const. 37, 289-300 (2004).

[19] C. F. Ferraris and F. de Larrard, Testing and Modeling of Fresh Concrete Rheology, NISTIR 6094, National Institute of Standards and Technology, Gaithersburg, MD, February 1998.

[20] W. R. Schowalter and G. Christensen, Toward a Rationalization of the Slump Test of the Fresh Concrete: Comparison of Calculations and Experiments, J. Rheol. 42 (4) 865-870 (1998).