Prevention of crack formation in massive concrete at an early age by cooling pipe system

Thermal cracking of massive concrete structures occurs as a result of stresses caused by hydration in real environment conditions. The extended finite element method that combines thermal fields and creep is used in this study to analyze the thermal cracking of massive concrete structures. The temperature field is accurately simulated through an equivalent equation of heat conduction that considers the effect of a cooling pipe system. The time-dependent creep behavior of massive concrete is determined by the viscoelastic constitutive model with Prony series. Based on the degree of hydration, we consider the main properties related to cracking evolving with time. Numerical simulations of a real massive concrete structure are conducted. Results show that the developed method is efficient for numerical calculations of thermal cracks on massive concrete. Further analyses indicate that a cooling system and appropriate heat preservation measures can efficiently prevent the occurrence of thermal cracks.

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Improving Heat Exchange Performance of Massive Concrete Using Annular Finned Cooling Pipes

Advances in Materials Science and Engineering ◽

10.1155/2021/5520949 ◽

2021 ◽

Vol 2021 ◽

pp. 1-14

Author(s):

Lemu Zhou ◽

Fangyuan Zhou ◽

Hanbin Ge

Keyword(s):

Concrete Block ◽

Finite Element Models ◽

Mass Concrete ◽

Pipe System ◽

Massive Concrete ◽

Exchange Performance ◽

Cooling Pipe ◽

Cooling Pipes ◽

Method Analysis ◽

Peak Value

Cracks will be generated due to high internal temperature of the massive concrete. Postcooling method is widely employed as a standard cooling technique to decrease the temperature of the poured mass concrete. In this paper, an annular finned cooling pipe which can increase the heat transfer area between the flowing water and its surrounding concrete is proposed to enhance the cooling effect of the postcooling method. Analysis of the interior temperature variation and distribution of the concrete block cooled by the annular finned cooling pipe system and the traditional cooling pipe system was conducted through the finite element models. It is found that, for the concrete block using the proposed annular finned cooling pipe system, the peak value of the interior temperature can be further lowered. Compared with the traditional cooling pipe, the highest temperature of concrete with an annular finned cooling pipe appears earlier than that with the traditional cooling pipe.

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Predicting the strength of massive concrete from the results of its ultrasonic testing at an early age

Hydrotechnical Construction ◽

10.1007/bf02305227 ◽

1980 ◽

Vol 14 (12) ◽

pp. 1280-1285

Author(s):

G. N. Kuleshov

Keyword(s):

Ultrasonic Testing ◽

Early Age ◽

Massive Concrete

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cooling pipe system

Dictionary Geotechnical Engineering/Wörterbuch GeoTechnik ◽

10.1007/978-3-642-41714-6_34763 ◽

2014 ◽

pp. 293-293

Keyword(s):

Pipe System ◽

Cooling Pipe

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5309 Design of Cooling Pipe System in Plastic Injection Die : Consideration of Evaluation Methods of Optimality

The proceedings of the JSME annual meeting ◽

10.1299/jsmemecjo.2006.7.0_271 ◽

2006 ◽

Vol 2006.7 (0) ◽

pp. 271-272

Author(s):

Tadayoshi MATSUMORI ◽

Koetsu YAMAZAKI ◽

Yoshio MATSUI

Keyword(s):

Evaluation Methods ◽

Pipe System ◽

Cooling Pipe ◽

Plastic Injection

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Fly-Ash Concretes of 50% of the Replacement Ratio to Reduce the Cracking in Concrete Structures

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.405-408.2665 ◽

2013 ◽

Vol 405-408 ◽

pp. 2665-2670 ◽

Cited By ~ 1

Author(s):

Ming Jie Mao ◽

Qiu Ning Yang ◽

Wen Bo Zhang ◽

Isamu Yoshitake

Keyword(s):

Fly Ash ◽

Concrete Structures ◽

High Volume ◽

Pozzolanic Reaction ◽

Strength Development ◽

Early Age ◽

Replacement Ratio ◽

Fly Ash Concrete ◽

Massive Concrete ◽

Normal Strength

Fly-ash concrete used in massive concrete structure has superior advantages to reduce hydration heat. On the other hand, the fly-ash concrete has negative property of low strength development at early age because pozzolanic reaction of fly-ash activates at mature age, such as after 28 days. To investigate these characteristics of fly-ash used in concrete, the present study discusses thermal cracking possibility of fly-ash concrete by using FE analysis software. The present study employs prediction formulae proposed by Zhang and Japanese design code in the simulations. The objects in this study are normal strength concrete mixed of fly-ash up to 50% of replacement ratio to cement. The comparative investigations show that temperature effect is more significant than strength development at early age. Based on the analytical study, high volume fly-ash concretes of 30-50% of the replacement ratio can be concluded as effective and useful materials to reduce the cracking possibility in massive concrete structures. Keywords-Fly-ash concrete; Early Age, Prediction Formulae for Strength; Thermal Stress Analysis

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