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Beton basınç dayanımının ultrasonik ses dalgası yayılma hızı ile tahmin edilmesi

Prediction of compressive strength of concrete through using ultrasonic pulse velocity

Journal Name:

  • Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi

Publication Year:

  • 2017

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
Since seismicity is active in Turkey, most of the buildings are vulnerable against earthquake excitation. So, inspections of buildings are vital. Concrete is one of the most important parameter effect the performance of the building. Obtaining concrete strength is also one of most challenge in inspection of the building. Classical technique, which require taking a piece of concrete for mechanical testing causes more labor, time and costs. So a simple method required especially in case of quick inspection of the building. Ultrasonic pulse velocity is one of the well-known techniques for nun destructive evaluation of concrete. The technique is easy, fast and require less labor. However it is not reliably by itself. In order to increase reliability, match curve must be prepared for every different concrete type. So, this study intended to developed models for concrete used in Diyarbakir district. This study both includes experimental and empirical work. In the experimental part, twelve cube specimens were produced from concrete work of different stories of a building being retrofitted in Diyarbakir. Dimension of cubes are 150 mm and all the cubes were cured 28 days in water. All the specimen was tested after at least 28 days. Ultrasonic pulse velocity (UPV) tests were carried out at first. For each specimen UPV tests were carried out at five different points and UPV values for each specimen was evaluated as average of these five values. After UPV tests compression tests were carried out for all specimen. For compression tests, monotonically axial load was increased until failure and the maximum load was marked. After all the UPV and compression tests were carried obtained data were used for developing a model to predict compressive strength of concrete from UPV values. In model, developing regression analysis was utilized. Data analyzed to obtained reasonable relation between UPV and compression strength. As a result, two different equations were developed (Equation 1 and Equation 2). As seen in Equations 1-2 only UPV values required to predict compressive strength of inspected concrete. f`c=21.77×UPV-53.26 (1) f`c=22.95×UPV-57.55 (2) In these equations UPV and f`c values must be in km/s and MPa units, respectively. The last part of this study is the performances evaluation of constructed models. To check prediction performance of the models a bunch of data was collected from literature. Our data was not used in the performance evaluation to make an objective evaluation. Totally 100 data was collected from 11 different researches. All the data are of normal concrete and of cube specimens. To reach a comment for necessity of our equations, a comparison was made between our equations and few equations from literature. Compressive strength of concrete was predicted for 100 data with our equations together with equations from literature. Statistical parameters such as average and relative error were used in performance evaluation. For the best model average of predicted and experimental compressive strength should be nearest one and relative error should smallest. Statistical evaluation parameters for all models are given as follow,As can be seen in the table in this table average is nearest one for Equation 1 and also relative error is the smallest. So, we can conclude that for the data grope was used, equation 1 is the best in prediction of the compressive strength from UPV.
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Abstract (Original Language): 
Betonarme binaların dayanımlarının hızlı bir şekilde belirlenmesinde beton dayanımının kolay bir şekilde tespiti kilit bir öneme sahiptir. Bu çalışmada beton basınç dayanımının pratik, kolay ve yapıya zarar vermeyecek bir şekilde belirlenmesi hedeflenmiştir. Bu nedenle hasarsız bir yöntem olan ultra ses dalgası yayılma hızından faydalanılmıştır. Bu çalışma çerçevesinde yapılan deneysel ve istatiksel değerlendirme çalışmaları neticesinde ultra ses dalgasının beton içindeki yayılma hızı ile beton basınç dayanımı arasında ampirik bir model geliştirilmiştir.
FULL TEXT (PDF): 
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REFERENCES

References: 

Abdullatif, A.M., (1997). Compatibility of Gypsum
Content in Concrete Ingredients. M.Sc Thesis,
University of Baghdad.
Ali M.A. and Al-Jaberi A.L., (2014). Evaluation of
Compressive Strength by Non- Destructive Test
UsingUltrasonic Pulse Velocity With
Maximum Size Aggregate (10 And 20)mm.
Journal of Engineering and Development, Vol.
18, No.3, May2014,ISSN 1813- 7822.
Al-Hesnawi K.A., (2011). Constructing a
Mathematical Models to Predict Some
Properties of Concrete from Non-Destructive
Testing, M.Sc., Thesis, College of Engineering,
University of Babylon.
Ahmed S.M., (2013). Effect of The Elevated
Temperature on Some Mechanical Properties of
Self Compacting Concrete Reinforced by Steel
Fiber, M.Sc., Thesis, College of Engineering,
University of Babylon.
Bedirhanoglu, I., Ilki, A., Pujol, S. and Kumbasar,
N., (2010). ,Seismic behavior of joints built
Modeller Ortalama Rölatif
Hata
Denklem 1 1.052 0.177
Denklem 2 1.072 0.196
Rouf ve diğ. (1986) 0.761 0.249
Nashn’t ve diğ. (2005) 0.718 0.290
TS 13791 (2010) 0.511 0.524
49
Beton basınç dayanımının ultra ses dalgası yayılma hızı ile tahmin edilmesi
with plain bars and low-strength concrete”, ACI
Struct. J., 107(3), 300-310.
Bedirhanoglu, I., (2014). A practical neuro-fuzzy
model for estimating modulus of elasticity of
concrete, Struct.Eng.Mech., 51(2), 249-265.
Demirboga R., Türkmen I. and Karakoc M.B.,
(2004). Relationship between ultrasonic
velocity and compressive strength for highvolume
mineral-admixtured concrete. Cement
and Concrete Research, Vol. 34, No. 12, pp.
2329–2336.
Excel (2007). Microsoft Excel programı.
IS. (1992). Non-destructive testing of concrete
methods of test, part1, IS, 13311.by, bureau of
indian standards، manak bhavan,9 bahadur shah
zafar maro new delhi 110002
Karim, M.M., (2005). Investigation of the Behavior
and Properties of Reinforced Concrete Slabs
Exposed to Fire Flame. M.Sc., Thesis, College of
Engineering, College of Engineering, University
of Babylon.
Madandoust R., Ghavidel R. and Nariman-Zadeh N.,
(2010). Evolutionary design of generalized
GMDH-type neural network for prediction of
concrete compressive strength using UPV.
Computational Materials Science, Vol. 49, pp.
556–567
Mahure V.N, Vijh K.G., Sharma P., Sivakumar N.,
Ratnam M., (2011). Correlation between pulse
velocity and compressive strength of concrete.
International Journal of Earth Sciences and
Engineering, ISSN 0974-5904, Volume 04, No
06 SPL, October 2011, pp 871-874.
Matar, G.S. (2000), "The armed resistance of
concrete fibers reinforced to attack the internal
sulphates" Master's thesis, University of
Baghdad, in 2000.
Musmar A.M and Alhadi A.N., (2007). Relationship
between ultrasonic pulse velocity and standard
concrete cube crushing strength, journal of assiut
university, vol. 36,NO. 1, pp. 51-59, January
2008.
Nash’t I. H., A’bour S. H., Sadoon A. A. (2005).
Finding an united relationship between crushing
strength of concrete and non-destructive tests,
Proceedings of Middle East Non-destructive
Testing Conference & Exhibition, Bahrain.
Neville, A. M (1995). Properties of concrete, 4th
edition, Longman Group Limited.
Obeed A.T., (2007).Effect of Exposure to Fire
Flame on Some Mechanical Properties of
SelfCompacting Concrete Using Different Types
of Filler, M.Sc., Thesis, College of Engineering,
University of Babylon.
Rao K. s., Sravana P. , Rao C. T. ,(2016).
Relationship between Ultrasonic Pulse Velocity
and Compressive Strength for Roller Compacted
Concrete containing GGBS. International Journal
of Applied Engineering Research ISSN 0973-
4562 Volume 11, Number 3 (2016) pp 2077-
2084.
Rajagopalan P.R., Prakash J. and NaramimhanV.
(1973). Correlation between ultrasonic pulse
velocity and strength of concrete. Indian
Concrete. Journal, Vol. 47, No. 11, pp. 416–418.
Rouf, Z., Younis, F., Abdullatif, M. (1986). Control
of quality of the concrete via using Ultrasonic
vibration. National Center for laboratories
construction, 1986-in Arabic.
TS, (2010). Assessment of in-situ compressive
strength in structures and precast concrete
components. TS EN 13791, TÜRK
STANDARDLARI ENSTİTÜSÜ Necatibey
Caddesi No.112 Bakanlıklar/ANKARA ICS
91.080. 40.
Tharmaratram K. and Tan B.S. (1990) Attenuation
of ultrasonic pulse in cement mortar. Cement and
Concrete Research,Vol. 20, pp. 335–340.
Trtnik G., Kavcic F., Turk G., (2009). Prediction of
concrete strength using ultrasonic pulse velocity
and artificial neural networks UltrasonicsVol. 49,
pp. 53–60.
Tumendemberel B. and Baigalimaa Ts. (2010).
Research Into The Correlation Between Concrete
Strenght and UPV Values, Centre of NDT, 10th
European Conference on Non-Destructive
Testing Contents of sections, Mongolian
University of Science and Technology.
Umran M.K., (2002). Fire Flame Exposure Effect on
Some Mechanical Properties of concrete, M.Sc.,
Thesis, College of Engineering, University of
Babylon.
Whitehurst E.A. (1951). "Use of the Soni scope for
Measuring Stetting Time of Concrete" ASTM
vol, 51, pp.1166-76.
Zabihi N.(2012). Effect of Specimen Size and Shape
on Strength of Concrete, Eastern Mediterranean
University January 2012 Gazimağusa, North
Cyprus, Approval of the Institute of Graduate
Studies and Research.

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