Interlaboratory study on rheological properties of cement pastes and reference substances: comparability of measurements performed with different rheometers and measurement geometries

Michael Haist; Julian Link; David Nicia; Sarah Leinitz; Christian Baumert; Tabea von Bronk; Dario Cotardo; Mahmoud Eslami Pirharati; Shirin Fataei; Harald Garrecht; Christoph Gehlen; Inga Hauschildt; Irina Ivanova; Steffen Jesinghausen; Christopher Klein; Hans-W. Krauss; Ludger Lohaus; Dirk Lowke; Oliver Mazanec; Sebastian Pawelczyk; Ursula Pott; Nonkululeko W. Radebe; Joachim Jiirgen Riedmiller; Hans-Joachim Schmid; Wolfram Schmidt; Egor Secrieru; Dietmar Stephan; Mareike Thiedeitz; Manfred Wilhelm; Viktor Mechtcherine

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Interlaboratory study on rheological properties of cement pastes and reference substances: comparability of measurements performed with different rheometers and measurement geometries

机译：水泥浆料和参考物质流变性能的逆向研究：用不同的流变仪进行测量的可比性和测量几何形状

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This paper presents the results of an interlaboratory study of the rheological properties of cement paste and ultrasound gel as reference substance. The goal was to quantify the comparability and reproducibility of measurements of the Bingham parameters yield stress and plastic viscosity when measured on one specific paste composition and one particular ultrasound gel in different laboratories using different rheometers and measurement geometries. The procedures for both in preparing the cement paste and carrying out the rheological measurements on cement paste and ultrasound gel were carefully defined for all of the study's participants. Different conversion schemes for comparing the results obtained with the different measurement setups are presented here and critically discussed. The procedure proposed in this paper ensured a reasonable comparability of the results with a coefficient of variation for the yield stress of 27% and for the plastic viscosity of 24%, despite the individual measurement series' having been performed in different labs with different rheometers and measurement geometries.

机译：本文介绍了水泥膏和超声凝胶作为参考物质的流变性能的互流性研究的结果。目的是当在使用不同的测压器和测量几何形状的不同实验室中测量，测量宾厄姆参数屈服应力和塑料粘度测量的可比性和再现性。为所有研究的参与者仔细地定义了在制备水泥糊和进行水泥糊和超声凝胶上的流变测量的程序。这里介绍了用于比较使用不同测量设置获得的结果的不同转换方案，并批判性讨论。本文提出的方法确保了结果的合理可比性，其变异系数为27％的屈服胁迫和24％的塑料粘度，尽管在不同的水管仪和不同的实验室中进行了各个测量系列的含量序列。测量几何形状。

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《Materials and structures》 |2020年第4期|92.1-92.26|共26页
作者
Michael Haist; Julian Link; David Nicia; Sarah Leinitz; Christian Baumert; Tabea von Bronk; Dario Cotardo; Mahmoud Eslami Pirharati; Shirin Fataei; Harald Garrecht; Christoph Gehlen; Inga Hauschildt; Irina Ivanova; Steffen Jesinghausen; Christopher Klein; Hans-W. Krauss; Ludger Lohaus; Dirk Lowke; Oliver Mazanec; Sebastian Pawelczyk; Ursula Pott; Nonkululeko W. Radebe; Joachim Jiirgen Riedmiller; Hans-Joachim Schmid; Wolfram Schmidt; Egor Secrieru; Dietmar Stephan; Mareike Thiedeitz; Manfred Wilhelm; Viktor Mechtcherine;
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作者单位

Institute for Building Materials Science Leibniz University Hannover 30167 Hannover Germany Until 01/2019: Institute of Concrete Structures and Building Materials Karlsruhe Institute of Technology (KIT) 76131 Karlsruhe Germany;

Institute for Building Materials Science Leibniz University Hannover 30167 Hannover Germany Until 01/2019: Institute of Concrete Structures and Building Materials Karlsruhe Institute of Technology (KIT) 76131 Karlsruhe Germany;

Institute of Building Materials Concrete Construction and Fire Safety Technische Universitat Braunschweig 38106 Braunschweig Germany;

Bundesanstalt fur Materialforschung und -pruefung (BAM) Division 7.4 Technology of Construction Materials 12205 Berlin Germany;

Institute of Construction Materials University of Stuttgart 70569 Stuttgart Germany;

Institute for Building Materials Science Leibniz University Hannover 30167 Hannover Germany;

Institute for Building Materials Science Leibniz University Hannover 30167 Hannover Germany;

Institute of Building Materials Concrete Construction and Fire Safety Technische Universitat Braunschweig 38106 Braunschweig Germany;

Institute of Construction Materials TU Dresden 01062 Dresden Germany;

Institute of Construction Materials University of Stuttgart 70569 Stuttgart Germany;

Centre for Building Materials Technical University Munich 81245 Munich Germany;

HeidelbergCement AG Oberklamweg 2-4 69181 Leimen Germany;

Institute of Construction Materials TU Dresden 01062 Dresden Germany;

Particle Technology Group Paderborn University 33098 Paderborn Germany;

Institute for Technical Chemistry and Polymer Chemistry Karlsruhe Institute of Technology (KIT) 76131 Karlsruhe Germany;

Institute of Building Materials Concrete Construction and Fire Safety Technische Universitat Braunschweig 38106 Braunschweig Germany;

Institute for Building Materials Science Leibniz University Hannover 30167 Hannover Germany;

Institute of Building Materials Concrete Construction and Fire Safety Technische Universitat Braunschweig 38106 Braunschweig Germany;

BASF Construction Solutions GmbH 83308 Trostberg Germany;

Particle Technology Group Paderborn University 33098 Paderborn Germany;

Building Materials and Construction Chemistry Technische Universitat Berlin 13355 Berlin Germany;

Institute for Technical Chemistry and Polymer Chemistry Karlsruhe Institute of Technology (KIT) 76131 Karlsruhe Germany;

BASF Construction Solutions GmbH 83308 Trostberg Germany;

Particle Technology Group Paderborn University 33098 Paderborn Germany;

Bundesanstalt fur Materialforschung und -pruefung (BAM) Division 7.4 Technology of Construction Materials 12205 Berlin Germany;

Institute of Construction Materials TU Dresden 01062 Dresden Germany;

Building Materials and Construction Chemistry Technische Universitat Berlin 13355 Berlin Germany;

Centre for Building Materials Technical University Munich 81245 Munich Germany;

Institute for Technical Chemistry and Polymer Chemistry Karlsruhe Institute of Technology (KIT) 76131 Karlsruhe Germany;

Institute of Construction Materials TU Dresden 01062 Dresden Germany;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Rheometry; Rheology; Interlaboratory test; Test setup; Testing procedure; Cement paste; Ultrasound gel;

机译：流变学;流变学;Interlaboratory测试;测试设置;测试程序;水泥膏;超声凝胶;

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Interlaboratory study on rheological properties of cement pastes and reference substances: comparability of measurements performed with different rheometers and measurement geometries

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