نشریه علمی شهر ایمن

نشریه علمی شهر ایمن

ارزیابی سازه‌های آسیب‌دیده پس از بحران با بهره‌گیری از آزمون"پیچش"

نوع مقاله : مقاله پژوهشی

نویسندگان
علی صابری ورزنه 1
محمود نادری 2
1 دکتری، دانشکده فنی و مهندسی، دانشگاه بین المللی امام خمینی (ره).
2 پروفسور، گروه عمران، دانشکده دانشکده فنی و مهندسی، دانشگاه بین المللی امام خمینی (ره)، قزوین، ایران.
10.22034/ispdrc.2025.2061738.1190
چکیده
طبق قانون مدیریت بحران، تاب‌آوری به معنای توانایی جامعه، برای ایستادگی در برابر حوادث می‌باشد. یکی از مراحل مدیریت بحران جهت تاب‌آوری شهری، پیشگیری و کاهش‌خطر می‌باشد. خسارات وارده به سازه‌های شهری بعد از زلزله دارای عواقبی مانند کاهش تاب‌آوری و عدم امدادرسانی بموقع به شهروندان می‌گردد. تعیین مقاومت درجای بتن سازه‌های موجود، بدون تخریب می‌تواند دید مناسبی از مقاومت و تحمل آن در برابر زلزله ارائه کند. اما روش‌های غیرمخرب، یا مقاومت را بصورت غیرمستقیم اندازه‌گیری می‌نمایند یا مانند آزمون "کشیدن از سطح" دارای دستگاه وارداتی و گران‌قیمتی می‌باشد. در این مقاله با بکارگیری آزمون نوین "پیچش" اقدام به ارزیابی مقاومت درجای نمونه‌های بتنی با مقاومت‌های مختلف گردیده و با ارائه نمودار کالیبراسیون، مقاومت برخی سازه‌های شهری بدون تخریب و بصورت مستقیم اندازه‌گیری شده و می‌توان در صورت نیاز نسبت به مقاوم‌سازی آن‌ها جهت کاهش آسیب‌های زلزله اقدام نمود. با انجام آزمون "پیچش" روی تعدادی سازه بتنی مشخص گردید تعدادی از آن‌ها نیاز به مقاوم‌سازی دارند تا بعد از زلزله بتوان از آن‌ها بهره‌برداری نمود. وجود ضریب همبستگی 95/0 بین آزمون "پیچش" و آزمون استاندارد نشان از دقت بالای آزمون فوق می‌باشد. با عکسبرداری SEM مشاهده شد که بتن تحت عمل‌آوری در آب دارای یکپارچگی بوده و تخلخل زیادی در آن‌ها مشاهده نمی‌شود.
کلیدواژه‌ها
مدیریت بحران
خسارت سازه ای
آزمون درجای پیچش
مقاومت فشاری بتن
رگرسیون
موضوعات

عنوان مقاله English

Evaluation of damaged structures after a crisis using “Twist-off” testing

نویسنده English

Mahmood Naderi 2
2 Professor, Civil Engineering Faculty, Imam Khomeini International University, Qazvin, Iran.
چکیده English

Introduction
The purpose of this article is to provide calibration curves for measuring the compressive strength of existing concrete structures using the "Twist-off" test. With the simple, inexpensive, and accurate "Twist-off" method, the compressive strength of many structures can be estimated in the shortest possible time and, if necessary, they can be reinforced before a crisis occurs so that less damage is caused to the structures after the crisis and loss of life and property can be prevented. Many laboratory studies have been conducted using the "Twist-off" test. In previous studies on concrete with different treatments, a correlation coefficient of about 0.94 was obtained between the results of the "Twist-off" test and the strength of concrete. In another study that used the "Twist-off" test to measure the compressive strength of cement mortars, it was concluded that the above test has a good accuracy. Also, the relationship between the modulus of rupture of pozzolanic concrete beams and the results of the "Twist-off" test also indicates the high accuracy of the above test for measuring various characteristics of pozzolanic concrete.
Methodology
In the in-situ "Twist-off" test, a steel cylinder with a radius of 25 mm is glued to the concrete surface and a torsional moment is applied to it. The equipment and supplies used in this test are very simple and inexpensive. The damage to the concrete in this test is very superficial and insignificant.
Results and discussion
Using power statistical analysis, it is observed that the correlation coefficient is above 95%, which indicates the high accuracy of the in-situ "Twist-off" test for evaluating the compressive strength of concretes with different strength classes. Therefore, in order to measure the in-situ strength of concretes, using the "Twist-off" method, the torsional moment obtained from the above test can be used to convert it into concrete strength and by using the power calibration curve. Concrete water tanks and concrete retaining walls have adequate compressive strength and therefore do not require reinforcement. However, the concrete bridges tested in this study and the concrete foundation do not have adequate compressive strength and a solution must be devised to reinforce them so that they can still be used after an earthquake. Before this study, standard cores had to be removed from the concrete to measure the compressive strength of existing concrete structures or elements and then tested in the laboratory. This would cause destructive damage to the structure. Or, the in-situ "pull-off" test had to be used, which requires an imported and very expensive device.
Conclusion
In this study, to measure the in-situ compressive strength of concrete structures, a new and in-situ "Twist-off" test was introduced and initially the results were compared with the results of the standard test. Then, laboratory samples and real concrete structures were evaluated using the above test. The results are as follows:
1- According to the country's crisis management law, cities must become resilient to upcoming crises. One of the issues of resilience is the need to know the compressive strength of existing concrete structures of different ages.
2- Given the accuracy of the new and in-situ "Twist-off" test, the compressive strength of existing structures can be measured with high accuracy without the need to destroy concrete.
3- By comparing the in-situ "Twist-off" test and the standard laboratory compressive strength test, it was determined that there is a power relationship with a correlation coefficient of over 95 percent between the results, which indicates the accuracy of the "torsion" test in assessing the in-situ compressive strength of concrete.
4- By performing a "twist" test on a number of existing concrete structures in Tehran, it was determined that a number of them need to be reinforced so that they can be used after the earthquake. Therefore, it is necessary to evaluate their compressive strength using the above test without destroying the concrete of the structures.
5- Using SEM photography, it was observed that the concrete samples under water curing had integrity and no large porosity was observed in them. However, insufficient curing caused the formation of extensive networks of fine pores in the microstructure of the concrete.
Funding
This work is based upon research funded by Iran National Science foundation (INSF) under project No. 4030409.
Authors’ Contribution
Authors contributed equally to the conceptualization and writing of the article. All of the authors approved thecontent of the manuscript and agreed on all aspects of the work declaration of competing interest none.
Conflict of Interest
Authors declared no conflict of interest.
Acknowledgments
We are grateful to all the scientific consultants of this paper.

کلیدواژه‌ها English

Crisis Management
Structural Damage
Insitu Twist off Testing
Strength
of Concrete
Regression
Alexander, M., Bentur, A., & Mindess, S. (2017). Durability of concrete: design and construction (Vol. 20). CRC Press.
ASTM C127. (2012). Standard test method for density, relative density (specific gravity), and absorption of fine aggregate, West Conshohocken PA, American Society for Testing and Materials.
ASTM C128. (2015). Standard test method for relative density (specific gravity) and absorption of coarse aggregate, West Conshohocken PA, American Society for Testing and Materials.
ASTM C136. (2006). Standard test method for sieve analysis of fine and coarse aggregates, West Conshohocken PA, American Society for Testing and Materials.
ASTM C1583/C1583M-13. (2013) Standard Test Method for Tensile Strength of Concrete Surfaces and the Bond Strength or Tensile Strength of Concrete Repair and Overlay Materials by Direct Tension (Pull-off Method), ASTM International, West Conshohocken, PA.
ASTM C597-16. (2016). Standard Test Method for Pulse Velocity Through Concrete, ASTM International, West Conshohocken, PA.
ASTM C808/C805M-18. (2018) Standard Test Method for Rebound Number of Hardened Concrete, ASTM International, West Conshohocken, PA.
Building and Housing Research Center (BHRC). (2008) The National Method for Concrete Mix Design.
Celik, G., & Ozdemir, M. (2025). Determination of concrete compressive strength from surface images using a CNN–SVR hybrid model. Measurement, 235, 113541. https://doi.org/10.1016/j.measurement.2024.113541.
INBR. (2022). Design and Construction of Reinforced Concrete Buildingsو Part 9 of the Iranian National Building Regulations, Iran.
Khoudja, A., Said, K., Mohamed, G., Zoubir-Mehdi, S., & Sidi-Mohammed, E. (2023). Analysis of the accuracy of in-situ concrete characteristic compressive strength assessment in real structures using destructive and non-destructive testing methods, Construction and Building Materials, 366, 130161. https://doi.org/10.1016/j.conbuildmat.2022.130161.
Kosmatka, S. H., Panarese, W. C., & Kerkhoff, B. (2002). Design and control of concrete mixtures Skokie, IL: Portland Cement Association. Vol. 5420. 60077-1083.
Krishna, K., Lam, E., Tung, C., Chau, Y., & Jang, J. (2024). Modified pull-off test evaluation of bond properties in preplaced aggregate concrete incorporating silica fume, Journal of Building Engineering, 82, 108264. https://doi.org/10.1016/j.jobe.2023.108264.
Naderi, M. (2007) New Twist-Off Method for the Evaluation of In-Situ Strength of Concrete, Journal of Testing and Evaluation. 35(6). ISSN: 0090-3973.
Naderi, M., & Kaboudan, A. (2021). Experimental study of the effect of aggregate type on concrete strength and permeability. Journal of Building Engineering 37, 101928. https://doi.org/10.1016/j.jobe.2020.101928.
Naderi, M., & Rahbari, R. (2021). Efficiency of coating layers used for harsh environmental conditions protection of CFRP-strengthened concrete, Journal of Building Engineering, 44, 102892. https://doi.org/10.1016/j.jobe.2021.102892.
Osman, H., & Fam, A. (2025). Pull-out strength of cast-in versus post-installed connectors in thin ultra-high performance concrete panels with polyoxymethylene fibers, Journal of Building Engineering, 103, 112078. https://doi.org/10.1016/j.jobe.2025.112078.
Parhizkari, M., Saberi Vaezaneh, A., & Naderi, M. (2022) The effect of penetration-reducing materials on concrete permeability and strength with “cylindrical chamber” and “Twist-off” tests. Amirkabir Journal of Civil Engineering. 55(1). pp.1-10.
Parihar, H., Shanker, R., & Singh, V. (2022). Effect of variation of steel reinforcement on ultrasonic pulse velocity prediction in concrete beam, Materials Today: Proceedings, 65(2), pp.1486-1490. https://doi.org/10.1016/j.matpr.2022.04.468.
Saberi Vaezaneh, A., Naderi, M., & Parhizkari, M. (2023) The effect of acute environmental conditions on water penetration rate and surface strength of concretes containing fibrous microsilica gel and super gel using in situ tests. Concrete research. 16(3). pp.31-43.
Saberi Vaezaneh, A., Naderi, M., & Parhizkari, M. (2024) The Effects of Extreme Environments on Concrete Surface Layer and Durability and Using Permeability-Reducing Admixtures to Prevent Permeability of Harmful Liquids. Amirkabir J. Civil Eng., 8(2). pp.127-144.
Saberi Varzaneh, A. & Naderi, M. (2020) determining the in-situ compressive and bending strengths of pozzolanic concrete containing polypropylene and glass fibers using “twist-off” method. Scient. J. of Civil Eng, 20(5).
Saberi Varzaneh, A., & Naderi, M. (2023). Comparing the Twist-off results and the CEB-FIP MODEL CODE standard to evaluate the adhesion of mortar/steel and provide a correction coefficient. Sharif civil engineering. 39(3), pp.131-138. https://doi.org/10.24200/J30.2023.61417.3170.
Saberi Varzaneh, A., Naderi, M. (2021). Determination of Shrinkage, Tensile and Compressive Strength of Repair Mortars and Their Adhesion on the Concrete Substrate Using
"Twist-off" and "Pull-off" Methods. Iran J Sci Technol Trans Civ Eng 45, pp.2377–2395. https://doi.org/10.1007/s40996-020-00548-w
Saleh, E., Tarawneh, A., Dwairi, H., & AlHamaydeh, M. (2022). Guide to non-destructive concrete strength assessment: Homogeneity tests and sampling plans, Journal of Building Engineering, 49, 104047. https://doi.org/10.1016/j.jobe.2022.104047.
Siddiqui, M. S., Nyberg, W., Smith, W., Blackwell, B., & Riding, K. A. (2013). Effect of curing water availability and composition on cement hydration. ACI Materials Journal, 110(3), 315-322.
Springenschmid, R. (2007) Betontechnologie für die Praxis, 1st ed.; Beuth Verlag GmbH: Berlin, Germany.
Taylor, H. F. (1997). Cement chemistry London: Thomas Telford. Boooook. Vol. 2, p.459.
Teriqet, A., Mohammadi., M., & Medras, Y. (2019). Thermodynamic investigation of hydration and chemical shrinkage of cement containing slag. Sharif. J. of Civil Eng, 34(4), pp.42-57.
The country's crisis management law. (2019). National Crisis Management Organization. Iran. pp. 1-23.
Wang, C., Zhou, M., Zhang, L., & Huang, H. (2025). Automated nondestructive evaluation of compressive strength of underground lining structure using hyperspectral imaging and deep neural networks. Journal of Rock Mechanics and Geotechnical Engineering. In Press. https://doi.org/10.1016/j.jrmge.2025.06.007.