Model of shear test for tearing strength of concrete

Introduction. To control the concrete strength of reinforce concrete structures the shear test based on the empirical proportional dependence of concrete strength and tear force of a special purpose anchor with an expanding cone is used. The absence of a physical model of a concrete deterioration when tearing strength is a sign of the defect of the method which hampers the search of the ways for accuracy increase and test validity. The purpose of this study is to develop a physical model of concrete deterioration to determine the calculated strength by the shear test.

Materials and methods. The concrete strength model is a mechanism for local deterioration by tearing out a body of concrete in the form of an indicative cone when extracting it from a pre-fabricated anchor well. It is accepted that the deterioration occurs in two stages: from the melting of the concrete to the formation of cracks in the plane of the apex of the concrete cone in the first stage and the subsequent formation of cracks along the lateral surface of the cone during the extraction of the anchor. For transition to compression resistance, the average of the ratio of concrete resistance to compression and tensile or Fere formula shall be used. The model was verified by the calculation of 6 test measurements.

Conclusions. It has been established that the empirical correlation between the resistance of concrete to compression and the force of extraction of the anchor in the concrete test is only possible if the resistance of concrete is linearly related to compression and extension. However, the actual ratio of concrete resistance to compression and tensile is non-linear, so for relatively weak concrete the possibility of overestimating the strength of concrete on compression empirical dependence is offset by a reduction factor, and for more durable concrete, measurements are underestimated.

1. Volf I.V., etc. Opredelenie prochnosti betona v konstruktsiyach metodom vyryvaniya sterzhney [Determination of the strength of concrete in structures by pulling out rods]. Beton I zhelezobeton [Concrete and reinforced concrete]. 1973. № 10. Pp. 20-22. (In Russian)

2. Saleem M., Hasir M. Bond Evaluation of Concrete Bolts Subjected to Impact Loading [Оценка сцепления бетонных болтов, подвергнутых ударной нагрузке]. Journal of Materials and Structures 2016. 49(9). Pp. 3635-3646.

3. Hoehler M., Eligehausen R. Behavior and testing of anchors in simulated seismic cracks. ACI Structural Journal, 2008. 105(3). Pp. 348-357.

4. EN 1992-4. 2018 Eurocode 2 – Design of concrete structures – Part 4: Design of fastenings for use in concrete – CEN, Brussels, 2018.

5. ETAG 001 Guidline for European technical approval of metal anchors for use in concrete – EOTA, Brussels, 2013.

6. ACI 318-14 Building Code Requirements for Structural Concrete – American Concrete Institute, 2014.

7. Ulybin A.V., Zubkov S.V., Fedotov S.D. Oshibka opredeleniya prochnosti betona metodom otryva so skalyvaniem [Error in determining the strength of concrete by the method of separation with chipping] // Nauchnye Trudy Obshchestva zhelesobetonshchikov Sibiri I Urala [Scientific works of the Society of Reinforced Concrete Workers of Siberia and the Urals]. Novosibirsk. SGUPS. 2016. 12: 1-7. (In Russian)

8. Petrakov A.N., Bukin A.V. Opredelenie prochnosti betona metodami razrushayushchego I nerazrushayushchego kontrolya [Determination of concrete strength by destructive and non-destructive testing methods]. // Vestnik Permskogo natsionalnogo issledovatelskogo politekhnicheskogo universiteta. 2010. № 1: 89-94. (In Russian)

9. Ulybin A.V. O vybore metodov kontrolya prochnosti betona postroennykh sooruzheniy [On the choice of methods for monitoring the strength of concrete constructed structures]. Inzhenerno-stroitelny zhurnal. 2012. № 4: 10-15. (In Russian)

10. Leonovich S.N., Snezhkov D.Yu. Issledovanie neravnoprochnosti betona na ob’ekte monolitnogo stroitelstva kompleksnym nerazrushayushchim metodom kontrolya [Investigation of non-uniform strength of concrete at a monolithic construction site by a complex non-destructive testing method]. Izvestiya VUZov Stroitelstvo. 2009. 8 (608): 108-115. (In Russian)

11. Korevitskaya M.G., Tuchtaev B.Kh., Ivanov S.I. Primenenie nerazrushayushchikh metodov pri kontrole prochnosti vysokoprochnogo betona [Application of non-destructive methods for testing the strength of high-strength concrete]. Promyshlennoe I grazhdanskoe stroitelstvo. 2013. № 1: 53-54. (In Russian)

12. Proektirovanie ankernykh krepleniy stroitelnykh konstruktsiy I oborudovaniya [Design of anchorages of building structures and equipment]. Moskow. 2018. 106 с. (In Russian)

13. FRP reinforcement in RC structures. Technical report prepared by a working party of Task group 9.3. FIB bulletin 40 (September 2007).

14. Krasnoshchekov Y.V., Krasotina L.V., Pulido- Delgado J.L. Models of direct anchoring of reinforcement in concrete [Модели прямой анкеровки арматуры в бетоне]. Magazine of Civil Engineering. 2018. 79(3): 149-160.

15. Jansson, A., Lofgren I., Lundgren K., Gylltoft K. Bond of reinforcement in self-compacting steel-fibre- reinforced concrete. Magazine of Concrete Research, 2012, Volume 64(7): 617-630.

16. Tepfers, R.A. Theory of Bond Applied to Overlapped Tensile Reinforcement Splices for Deformed Bars. PhD thesis, Chalmers University of Technology. Go¨teborg, Sweden. 1973.

17. Krasnoshchekov Y.V. Modelirovanie raskalyvaniya betona v zone ankerovki nenapryagaemoy armatury [Modeling of concrete splitting in the anchoring zone of non-stressed reinforcement]. The Russian Automobile and Highway Industry Journal. 2017; 2: 64-69. (In Russian)

18. Krasnoshchekov Y.V., Krasotina L.V. O raschete prochnosti zhelezobetonnykh elementov po naklonnym secheniyam [Calculation of strength of reinforced concrete elements by inclined sections]. Promyshlennoe I grazhdanskoe stroitelstvo. 2020. 6: 17-25. (In Russian)