https://orcid.org/0000-0002-2435-8731
Abstract
In relatively deep structural members, re-vibration is applied to sequential layers after they are initially hardened. This may cause harmful effects on strength properties, especially on lightweight concrete (LWC). In this experimental study, the effects of re-vibration on LWC properties were thoroughly investigated. Local lightweight crushed pumice rock named “Bonza,” as well as set retarding admixture and silica fume (SF) were used to produce four different mixes of LWC. These mixes were re-vibrated at different time lags (0:00, 2:50, 4:30, and 5:30 [h:min]). After the re-vibration process, compressive and tensile strength properties, as well as pulse velocity, density, and permeable voids volume of hardened concrete mixes, were investigated. Results showed that using the setting retarder and partial SF replacement of Portland cement, the density, compressive, and tensile strength properties were increased in all re-vibrated mixes when the re-vibration was accomplished before the final set time of the cement. A lack of correlation between ultrasonic pulse velocity, density, and compressive strength was also detected. Furthermore, a linear relationship was found between permeable voids volume and compressive strength of all mixtures.
Issue Section:
Technical Manuscript
References
1.
A. M.
Neville
,
Properties of Concrete
(Harlow, UK
: Longman
, 2000
).2.
N.
Bozkurt
and
S.
Yazicioglu
, “Strength and Capillary Water Absorption of Lightweight Concrete under Different Curing Conditions
,”
Indian Journal of Engineering and Materials Sciences
17
, no. 2
(April 2010
): 145
–151
.3.
T. Y.
Lo
,
H. Z.
Cui
, and
Z. G.
Li
, “Influence of Aggregate Pre-wetting and Fly Ash on Mechanical Properties of Lightweight Concrete
,”
Waste Management
24
, no. 4
(2004
): 333
–338
,
4.
J. A.
Rossignolo
and
M. V. C.
Agnesini
, “Durability of Polymer-Modified Lightweight Aggregate Concrete
,”
Cement and Concrete Composites
26
, no. 4
(May 2004
): 375
–380
,
5.
H. K.
Ahmed
,
W. I.
Khalil
, and
M. D.
Subhi
, “Mechanical Properties of Fiberous High Performance Lightweight Aggregate Concrete
,”
Engineering and Technology Journal
35
, no. 3
(2017
): 229
–238
.6.
Guide for Structural Lightweight-Aggregate Concrete
, ACI 213R-14 (Farmington Hills, MI
: American Concrete Institute
, 2003
).7.
R.
Demirboğa
,
İ
Örüng
, and
R.
Gül
, “Effects of Expanded Perlite Aggregate and Mineral Admixtures on the Compressive Strength of Low-Density Concretes
,”
Cement and Concrete Research
31
, no. 11
(November 2001
): 1627
–1632
,
8.
B. A.
Kumar
,
G.
Sangeetha
,
A.
Srinivas
,
P. O.
Awoyera
,
R.
Gobinath
, and
V. V.
Ramana
, “Models for Predictions of Mechanical Properties of Low-Density Self-Compacting Concrete Prepared from Mineral Admixtures and Pumice Stone
,” in
Soft Computing for Problem Solving
(Singapore
: Springer, Singapore
, 2020
), 677
–690
.9.
K. S.
Chia
and
M.-H.
Zhang
, “Water Permeability and Chloride Penetrability of High-Strength Lightweight Aggregate Concrete
,”
Cement and Concrete Research
32
, no. 4
(April 2002
): 639
–645
,
10.
M. N.
Haque
,
H.
Al-Khaiat
, and
O.
Kayali
, “Strength and Durability of Lightweight Concrete
,”
Cement and Concrete Composites
26
, no. 4
(May 2004
): 307
–314
,
11.
M. M.
Kassim
, “Effects of Revibration on Early Age Retarded Concrete
,”
High Performance Structures and Materials VI
(Southampton, UK
: WIT Press
, 2012
): 85
–93
.12.
H. B.
Koh
,
D.
Yeoh
, and
S.
Shahidan
, “Effect of Re-vibration on the Compressive Strength and Surface Hardness of Concrete
,”
IOP Conference Series: Materials Science and Engineering
271
(2017
): 012057
,
13.
R. M. V.
Krishna
,
P. R.
Kumar
, and
N. V. R. C. B.
Bhaskar
, “Effect of Re-vibration on Compressive Strength of Concrete
,”
Asian Journal of Civil Engineering (Building and Housing)
9
, no. 3
(June 2008
): 291
–301
.14.
A.
Achalu
,
E. T.
Quezon
, and
G. B.
Macarubbo
, “A Study on the Effect of Time Duration by Vibrating or Tamping Fresh Concrete on the Compressive Strength of C-25 Concrete
,”
American Journal of Applied Scientific Research
3
, no. 6
(2017
): 72
–79
,
15.
P. O.
Awoyera
,
A. R.
Dawson
,
N. H.
Thom
, and
J. O.
Akinmusuru
, “Suitability of Mortars Produced Using Laterite and Ceramic Wastes: Mechanical and Microscale Analysis
,”
Construction and Building Materials
148
(September 2017
): 195
–203
,
16.
J. F.
Lamond
and
J. H.
Pielert
,
Significance of Tests and Properties of Concrete and Concrete-Making Materials
(West Conshohocken, PA
: ASTM International
, 2006
), https://doi.org/10.1520/STP169D-EB
17.
S. K.
Patel
,
R. K.
Majhi
,
H. P.
Satpathy
, and
A. N.
Nayak
, “Durability and Microstructural Properties of Lightweight Concrete Manufactured with Fly Ash Cenosphere and Sintered Fly Ash Aggregate
,”
Construction and Building Materials
226
(November 2019
): 579
–590
,
18.
Specification for Aggregates from Natural Sources for Concrete
(Superseded), BS 882:1992 (London
: British Standards Institution
, 1992
).19.
Standard Specification for Lightweight Aggregates for Structural Concrete
(Superseded), ASTM C330-04 (West Conshohocken, PA
: ASTM International
, approved January 1, 2004
), https://doi.org/10.1520/C0330-04
20.
F. A. M.
Mirza
, “Effect of Sand Replacement and Silica Fume Addition on Chloride Ion Permeability of Lightweight Concrete
,”
Journal of King Saud University - Engineering Sciences
20
, no. 1
(2009
): 61
–73
.21.
C.-W.
Tang
, “Effect of Presoaking Degree of Lightweight Aggregate on the Properties of Lightweight Aggregate Concrete
,”
Computers and Concrete
19
, no. 1
(January 2017
): 69
–78
,
22.
K.-C.
Thienel
,
T.
Haller
, and
N.
Beuntner
, “Lightweight Concrete—From Basics to Innovations
,”
Materials
13
, no. 5
(2020
): 1120
,
23.
Testing Concrete. Method for Determination of Compressive Strength of Concrete Cubes
, BS 1881-116:1983 (London
: British Standards Institution
, 1983
).24.
Standard Test Method for Pulse Velocity through Concrete
(Superseded), ASTM C597-09 (West Conshohocken, PA
: ASTM International
, approved December 15, 2009
), https://doi.org/10.1520/C0597-09
25.
Testing Concrete. Method for Determination of Tensile Splitting Strength
(Superseded), BS 1881-117:1983 (London
: British Standard Institution
, 1983
).26.
Standard Test Method for Density, Absorption, and Voids in Hardened Concrete
, ASTM C642-13 (West Conshohocken, PA
: ASTM International
, approved February 1, 2013
), https://doi.org/10.1520/C0642-13
27.
R. S.
Ahari
,
T. K.
Erdem
, and
K.
Ramyar
, “Permeability Properties of Self-Consolidating Concrete Containing Various Supplementary Cementitious Materials
,”
Construction and Building Materials
79
(March 2015
): 326
–336
,
28.
S. H.
Adnan
,
I. A.
Rahman
,
H. M.
Saman
, and
F.
Riza
, “Pozzolanic Properties of Micronized Biomass Silica in Enhancing Compressive Strength and Water Permeability of Concrete
,”
Modern Applied Science
6
, no. 11
(2012
): 1
–8
,
29.
I. A. R. M. A.
Rahman
, “Effect of Vibrations on Concrete Strength
” (master’s thesis, University of Khartoum, 2007
).30.
P. O.
Awoyera
,
I. I.
Akinwumi
,
V.
Karthika
,
R.
Gobinath
,
R.
Gunasekaran
,
N.
Lokesh
,
M.
Manikandan
, and
T.
Narmatha
, “Lightweight Self-Compacting Concrete Incorporating Industrial Rejects and Mineral Admixtures: Strength and Durability Assessment
,”
Silicon
(2019
).31.
H. P.
Satpathy
,
S. K.
Patel
, and
A. N.
Nayak
, “Development of Sustainable Lightweight Concrete Using Fly Ash Cenosphere and Sintered Fly Ash Aggregate
,”
Construction and Building Materials
202
(March 2019
): 636
–655
,
Copyright © 2020
by ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959
You do not currently have access to this content.
