1. INTRODUCTION
⌅Roller
compacted concrete pavement (RCCP) provides a sustainable means of
pavement construction, which follows the three sustainability pillars:
economic, social and environmental (11. Van Dam, T.; Taylor, P.; Fick, G.; VanGeem, M.; Lorenz, E. (2012) Sustainable concrete pavements: a manual of practice. https://www.semanticscholar.org/paper/Sustainable-Concrete-Pavements%3A-A-Manual-of-Dam-Taylor/773d1e391e13173dc27abffc74c5d186823d5c93.
).
Compared with Portland cement concrete (PCC), properties such as no
dowel or steel reinforcement, no finishing, rapid construction and quick
access to service and high durability has made RCCP an interesting
pavement material (1-31. Van Dam, T.; Taylor, P.; Fick, G.; VanGeem, M.; Lorenz, E. (2012) Sustainable concrete pavements: a manual of practice. https://www.semanticscholar.org/paper/Sustainable-Concrete-Pavements%3A-A-Manual-of-Dam-Taylor/773d1e391e13173dc27abffc74c5d186823d5c93.
2.
Zollinger, D.G. (2016) Roller-Compacted Concrete Pavement: [techbrief]
(No. FHWA-HIF-16-003). United States. Federal Highway Administration https://www.fhwa.dot.gov/pavement/pub_details.cfm?id=993.
3.
Harrington, D.; Abdo, F.; Adaska, W.; Hazaree, C.V.; Ceylan, H.;
Bektas, F. (2010) Guide for roller-compacted concrete pavements. https://lib.dr.iastate.edu/intrans_reports/102/.
).
The placement and compaction of RCCP is similar to asphalt pavement
construction. The constituents used in RCCP are identical to PCC, but in
different ratios. RCCP is a stiff concrete with no slump that has a
lower water demand and cement dosage in comparison to PCC (22.
Zollinger, D.G. (2016) Roller-Compacted Concrete Pavement: [techbrief]
(No. FHWA-HIF-16-003). United States. Federal Highway Administration https://www.fhwa.dot.gov/pavement/pub_details.cfm?id=993.
, 33.
Harrington, D.; Abdo, F.; Adaska, W.; Hazaree, C.V.; Ceylan, H.;
Bektas, F. (2010) Guide for roller-compacted concrete pavements. https://lib.dr.iastate.edu/intrans_reports/102/.
). Therefore, RCCP is dryer and stiffer than PCC (33.
Harrington, D.; Abdo, F.; Adaska, W.; Hazaree, C.V.; Ceylan, H.;
Bektas, F. (2010) Guide for roller-compacted concrete pavements. https://lib.dr.iastate.edu/intrans_reports/102/.
, 44.
Pittman, D.W. (1989) The Effects of the Construction Process on
Selected Fresh and Hardened Properties of Roller-Compacted Concrete
(RCC) Pavements. Army engineer waterways experiment station. Vicksburg
Ms Geotechnical Lab. https://apps.dtic.mil/sti/citations/ADA213735.
).
These characteristics of RCCP provide appropriate mechanical properties
that lead to less drying shrinkage in its construction. Drying
shrinkage is one of the significant causes of concrete deflections,
which appear on the surface of pavements in the first few days after
placement and eventually cause remarkable volume reduction. Most of the
reduced volume in concrete is due to loss of water in capillary and gel
pores (55. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
, 66. Cement Concrete and Aggregates Australia (2002) Drying Shrinkage of Cement and Concrete. https://www.ccaa.com.au/iMIS_Prod.
).
Due to the restraint of the pavement above the foundation, the volume
reduction would produce stress that can exceed the concrete tensile
strength (55. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
, 66. Cement Concrete and Aggregates Australia (2002) Drying Shrinkage of Cement and Concrete. https://www.ccaa.com.au/iMIS_Prod.
).
Drying
shrinkage is an inevitable phenomenon that eventually induces cracking
in a concrete member. It is affected by many factors such as aggregate,
cement, water, ambient conditions (temperature, humidity and wind
velocity), curing conditions and geometry (5-75. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
6. Cement Concrete and Aggregates Australia (2002) Drying Shrinkage of Cement and Concrete. https://www.ccaa.com.au/iMIS_Prod.
7. Avram, C. (1981) Concrete Strength and Strains, Elsevier Scientific Pub. Co. (1981).
).
In a half-century of RCCP establishment, a few researches were
published about the value and the influential factors of drying
shrinkage of RCCP. According to Khayat and Libre (88.
Khayat, K.H.; Libre, N.A. (2014) Roller compacted concrete: field
evaluation and mixture optimization (No. NUTC R363). Missouri University
of Science and Technology. Center for Transportation Infrastructure and
Safety. https://www.semanticscholar.org/paper/Roller-Compacted-Concrete%3A-Field-Evaluation-and-Khayat-Libre/002baa236c54e20a58991d675089cf08233b7fdb.
), the maximum drying shrinkage of RCCP is between 400 and 500 microstrain. However, Pittman and Ragan (99. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
)
reported that in RCCP, using proper mix proportions, water to cement
ratios and well-graded aggregates caused a lower drying shrinkage
deformation with an average of 150 microstrain at 28 days. Gholami and
Modarres (1010.
Gholami, N.; Modarres, A. (2019) Shrinkage behaviour of
superplasticised RCCP and its relationship with internal temperature. Inter. Pave. Engi. 20 [1], 12-23. https://doi.org/10.1080/10298436.2016.1244438.
) reported that the drying shrinkage value of RCCP is around 150 microstrain at 90 days while Jingfu et al. (1111.
Jingfu, K.; Chuncui, H.; Zhenli, Z. (2009) Strength and shrinkage
behaviors of roller-compacted concrete with rubber additives. Mater. Struc. 42 [8], 1117-1124. https://doi.org/10.1617/s11527-008-9447-x.
)
revealed that the 90 days drying shrinkage of RCCP is near to 200
microstrain. It should be noted that values were reported in specific
mix proportions and ambient conditions. Furthermore, in these
researches, the effect of aggregate in RCCP has not been investigated
comprehensively and some properties of RCCP were neglected, such as
workability and mechanical properties.
The principal variables of drying shrinkage in concrete are aggregate volume and water content (55. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
).
The aggregate consumption in RCCP is more than PCC while aggregate
usage in RCCP is 75-85% of the total volume, which is higher than 60-75%
in PCC (33.
Harrington, D.; Abdo, F.; Adaska, W.; Hazaree, C.V.; Ceylan, H.;
Bektas, F. (2010) Guide for roller-compacted concrete pavements. https://lib.dr.iastate.edu/intrans_reports/102/.
). Khayat and Libre (88.
Khayat, K.H.; Libre, N.A. (2014) Roller compacted concrete: field
evaluation and mixture optimization (No. NUTC R363). Missouri University
of Science and Technology. Center for Transportation Infrastructure and
Safety. https://www.semanticscholar.org/paper/Roller-Compacted-Concrete%3A-Field-Evaluation-and-Khayat-Libre/002baa236c54e20a58991d675089cf08233b7fdb.
)
reported that by increasing the volume of aggregate, the water to
cement ratio has less effect on drying shrinkage. It was revealed that
the mechanical properties of concrete are strongly influenced by
aggregate content. Hashemi et al. (1212.
Hashemi, M.; Shafigh, P.; Karim, M.R.B.; Atis, C.D. (2018) The effect
of coarse to fine aggregate ratio on the fresh and hardened properties
of roller-compacted concrete pavement. Const. Build. Mater. 169, 553-566. https://doi.org/10.1016/j.conbuildmat.2018.02.216.
)
reported that the coarse to fine aggregate ratio has a significant
effect on the mechanical properties of RCCP. Furthermore, the maximum
size of aggregate in concrete affects the mechanical properties and
drying shrinkage of concrete (1313.
Carlson, R.W. (1938) Drying shrinkage of concrete as affected by many
factors. American Soc Testing & Materials Proc. 38 [2], 419-437.
). In addition, it is admitted that by increasing aggregate content, drying shrinkage decreases due to aggregate restraint (13-1613.
Carlson, R.W. (1938) Drying shrinkage of concrete as affected by many
factors. American Soc Testing & Materials Proc. 38 [2], 419-437.
14. Rao, G.A. (2001) Long-term drying shrinkage of mortar-influence of silica fume and size of fine aggregate. Cem. Concr. Res. 31 [2], 171-175. https://doi.org/10.1016/S0008-8846(00)00347-1.
15. Pickett, G. (1956) Effect of aggregate on shrinkage of concrete and a hypothesis concerning shrinkage. J. Proceed. 52 [1], 581-590. https://doi.org/10.14359/11617.
16. Neville, A.M. (1995) Properties of concrete, forth Edition. By AM Neville.
). Therefore, the role of aggregate is substantial on the drying shrinkage of RCCP.
Although there are some studies on the influence of aggregate on the drying shrinkage of concrete, there is a lack of comprehensive studies on the influence of aggregate and coarse to fine aggregate ratio on the drying shrinkage of RCCP. Furthermore, limited data about the behavior of drying shrinkage of RCCP makes it essential to have a comprehensive investigation on it. Therefore, in this study the drying shrinkage of RCCP was investigated at different coarse to fine aggregate ratios. For this purpose, the drying shrinkage of RCCP in the short and long term, based on different coarse to fine aggregate ratios, was determined. In addition, hardened properties such as compressive, splitting tensile, flexural strengths and Vebe time test were investigated.
2. EXPERIMENTAL DESIGN
⌅2.1. Materials
⌅The grading curve of the combined coarse and fine aggregate was within Portland Cement Association (PCA) standard limits (1717. Kosmatka, S.H.; Wilson, M.L. (2016) Portland Cement Association; 16th edition.
), as shown in Figure 1.
The crushed granite as a coarse aggregate was used with a maximum
nominal size of 12 mm with SSD, specific gravity of 2.62 and 24 h water
absorption of 0.6%. Low fines content sand was mined locally with
fineness modulus, saturated surface-dry (SSD) specific gravity and 24 h
water absorption of 2.8, 2.55 and 1.5%, respectively.
Ordinary Portland cement with a 48 MPa compressive strength at 28 days was used. Specific gravity and specific surface area were 3.14 and 3510 cm2/g, respectively.
2.2. Mix proportions
⌅The mix proportions that are adopted in this research are shown in Table 1. Four different coarse to fine aggregate ratios including 0.7, 1, 1.2 and 1.5 in two cement dosages of 12% (269 kg/m3) and 15% (332 kg/m3) by mass of total dry solid were applied.
Mix ID | Cement | Water (kg/m3) | Coarse aggregate (Kg/m3) | Fine aggregate (Kg/m3) | Coarse to Fine aggregate ratio | 28-day Compressive strength (MPa) | Vebe time (s) | |
---|---|---|---|---|---|---|---|---|
% | Kg/m3 | |||||||
12A | 12 % | 269 | 108 | 812 | 1161 | 0.7 | 36 | 22 |
12B | 986 | 986 | 1 | 42 | 25 | |||
12C | 1076 | 897 | 1.2 | 47 | 28 | |||
12D | 1184 | 798 | 1.5 | 47 | 33 | |||
15A | 15 % | 332 | 133 | 776 | 1108 | 0.7 | 42 | 15 |
15B | 942 | 942 | 1 | 50 | 18 | |||
15C | 1028 | 857 | 1.2 | 51 | 20 | |||
15D | 1131 | 754 | 1.5 | 44 | 24 |
The freshly mixed concretes were compacted in cylindrical molds using an electric vibrating hammer according to ASTM C 1435 (1818.
ASTM C1435 / C1435M-14 (2014) Standard practice for molding
roller-compacted concrete in cylinder molds using a vibrating hammer.
Annual book of ASTM standards. Philadelphia (PA, USA): American Society
for Testing and Materials. https://doi.org/10.1520/c1435_c1435m-14.
).
In addition, prism molds were used for the flexural tensile strength
test. An electric vibrating hammer was used to prepare the prism
specimens, which was equipped with a shaft and rectangular plate.
Casting for prism specimens was fulfilled in three layers, and while the
compaction of each layer was performed, observation of mortar formation
on the top surface was carried out. Designation of the RCCP mixes was
performed in accordance with the soil compaction concept of the relevant
standards ASTM D1557 (1919. ACI 211.3R-02 (2002) Guide for selecting proportions for no-slump concrete.
).
2.3. Testing set-up and procedures
⌅The laboratory testing program was aimed at measuring the properties of RCCP in terms of workability, strengths and drying shrinkage strain. A modified Vebe test was employed to determine the consistency of RCCP. The hardened properties of concretes were measured by compressive strength, splitting tensile strength and flexural tensile strength tests at 28 days. Drying shrinkage strain of RCCP was measured by a demountable mechanical strain gauge (DEMEC).
2.3.1. Drying shrinkage
⌅To
measure drying shrinkage strain, six specimens with 100×100×300 mm
dimensions for each mix were prepared and then divided into two groups:
cured and non-cured. Three non-cured specimens were measured immediately
after demolding and three cured specimens were cured in lime-saturated
water for 7 days and were measured when taken out from the water. Both
groups were measured every day for the first 7 days, and then every 7
days for 90 days according to ASTM C157 (2020.
ASTM C157 / C157M-17 (2017) Standard test method for length change of
hardened hydraulic-cement mortar and concrete. ASTM International, West
Conshohocken, PA. http://doi.org/10.1520/C0157_C0157M-17.
). The testing apparatus was a DEMEC with an accuracy of 0.5 microstrain (Figure 2).
The average of six readings obtained as the drying shrinkage strain for
each age. The specimens were kept in the laboratory, which was an
uncontrolled room and had a temperature of 30 ± 2°C and 70 ± 5% relative
humidity.
2.3.2. Mechanical properties
⌅The compressive strength and splitting tensile strength tests were performed according to ASTM C39 (2121.
ASTM C39 / C39M-20 (2020) Standard test method for compressive strength
of cylindrical concrete specimens, ASTM International, West
Conshohocken, PA. http://doi.org/10.1520/C0039_C0039M-20
) and ASTM C496 (2222.
ASTM C496 / C496M-17 (2017) Standard test method for splitting tensile
strength of cylindrical concrete specimens. ASTM International, West
Conshohocken, PA. http://doi.org/10.1520/C0496_C0496M-17.
),
respectively. Compressive strength testing was fulfilled on cylinder
specimens of 100×200mm dimensions at 7 and 28 days whereas the splitting
tensile strength tests, which had the same specimen dimensions, were
accomplished at 28 days. On the other hand, the flexural tensile
strength test was performed on 100×100×500mm prism specimens according
to ASTM C78 (2323.
ASTM C78 / C78M-18 (2010) Standard test method for flexural strength of
concrete (using simple beam with third-point loading). ASTM
International, West Conshohocken, PA. http://doi.org/10.1520/C0078_C0078M-18.
).
2.3.3. Vebe test
⌅According to ASTM C1170 (2424.
ASTM C1170 / C1170M-20 (2010) Standard test method for determining
consistency and density of roller-compacted concrete using a vibrating
table. ASTM International, West Conshohocken, PA. http://doi.org/10.1520/C1170_C1170M-20.
),
a modified Vebe test was performed to attain the workability of each
mix proportion. Due to the stiffness of RCC mixes, its workability and
compaction possibility is very important.
3. RESULTS AND DISCUSSION
⌅3.1. Fresh properties
⌅The Vebe time and density for all RCCPs are presented in Table 1.
There was no segregation in all concrete mixtures during mixing,
placement and compaction. In other words, sufficient workability was
seen for all RCCPs. Sufficient workability is a critical parameter for
full compaction, uniform density, correct bonding with the last layer
and also for the tolerance of compaction equipment (2525. Yerramala, A.; Babu, K.G. (2011) Transport properties of high-volume fly ash roller compacted concrete. Cem. Conc. Comp. 33 [10], 1057-1062. https://doi.org/10.1016/j.cemconcomp.2011.07.010.
). As can be seen in Table 1,
the results show that the Vebe time decremented in cement dosage from
12% to 15% and incremented in coarse to fine aggregate ratio. Increasing
cement dosage resulted in higher paste volume and lower Vebe time,
which caused RCCP to have better compaction and finish (2626.
Hashemi, M.; Shafigh, P.; Abbasi, M.; Asadi, I. (2019) The effect of
using low fines content sand on the fresh and hardened properties of
roller-compacted concrete pavement. Case Stud. Const. Mater. 11, e00230. https://doi.org/10.1016/j.cscm.2019.e00230.
).
On the other hand, increasing the coarse to fine aggregate ratio from
0.7 to 1.5 with 12% and 15% cement increased the Vebe time by 50% and
60%, respectively. Hashemi et al. (1212.
Hashemi, M.; Shafigh, P.; Karim, M.R.B.; Atis, C.D. (2018) The effect
of coarse to fine aggregate ratio on the fresh and hardened properties
of roller-compacted concrete pavement. Const. Build. Mater. 169, 553-566. https://doi.org/10.1016/j.conbuildmat.2018.02.216.
)
reported that incrementing the coarse to fine ratio in RCCP between 0.6
and 1.8 incremented the Vebe time up to three times. However,
increasing cement from 12% to 15% decreased the Vebe time 28%. According
to Vahedifard et al. (2727.
Vahedifard, F.; Nili, M.; Meehan, C.L. (2010) Assessing the effects of
supplementary cementitious materials on the performance of low-cement
roller compacted concrete pavement. Const. Build. Mater. 24 [12], 2528-2535. https://doi.org/10.1016/j.conbuildmat.2010.06.003.
), incrementing the cement dosage in RCCP between 12% and 15% resulted in Vebe time reduction of 10%.
3.2. Mechanical properties
⌅Figure 3 to Figure 5Figs. 3, 4, 5 present the relationships between compressive, splitting tensile and flexural strengths and coarse to fine aggregate ratio for RCCPs consisting of 12% and 15% cement dosages at 28-day age. RCCPs with 12% cement exhibited an increment for the strengths of compressive, splitting tensile and flexural tensile about 30%, 15% and 32% when the coarse to fine aggregate ratio was changed from 0.7 to 1.2, respectively. Afterward, those strengths decreased around 0%, 15% and 4% when the coarse to fine aggregate ratio was changed from 1.2 to 1.5, respectively. In the second group, where the cement content was 15%, similar trends were monitored. The compressive and splitting tensile strengths as well as the flexural tensile strength incremented by about 21%, 17% and 19% with coarse to fine ratios of 0.7, 1 and 1.2, respectively. Subsequently, those strengths decreased by around 14%, 7% and 9% when the coarse to fine ratio incremented from 1.2 to 1.5, respectively.
As can be seen for all RCCPs with two cement dosages, the strengths of compressive, splitting tensile and flexural tensile reached the peak of the strengths at a coarse to fine aggregate ratio of 1.2. The reason could be due to higher pack-density and a more dense structure of RCCP with a coarse to fine aggregate ratio of 1.2.
ASTMC 330-89 specified that the cylinder compressive strength must be at least 17 MPa at 28 days (2828. Neville, A.M.; Brooks, J.J. (2008) Concrete Technology, Malaysia: Prentice Hall.
).
PCA demonstrated that the compressive strength is almost the same for
both RCCP and PCC, which is generally around 28-41 MPa. In addition, the
British Department for Transport (2929.
Calverley, M.A.A. (1977) The design of British airports authority
pavements. International Conference on Concrete Pavement Design. https://trid.trb.org/view/717615.
)
determined that the 28-day splitting tensile strength of a concrete
that is used in road construction should not be less than 1.8. Moreover,
the British Airports Authority (BAA) noted that the minimum 28-day
flexural tensile strength of a concrete must be 4 MPa (2929.
Calverley, M.A.A. (1977) The design of British airports authority
pavements. International Conference on Concrete Pavement Design. https://trid.trb.org/view/717615.
). The current test results determine that all RCCPs are above requirements.
3.3. Drying shrinkage
⌅The average drying shrinkage strain development of RCCP specimens over 90 days in cured and non-cured conditions was determined. Therefore, the role of the coarse to fine aggregate ratio on the drying shrinkage of RCCPs was compared and investigated in both conditions. Furthermore, the drying shrinkage values were compared with previous studies.
3.3.1. Non-cured condition
⌅
Figure 6
shows the effect of the coarse to fine aggregate ratio (from 0.7 to
1.5) on the drying shrinkage strain values of RCCPs with 12% and 15%
cement content. As can be seen in Figure 6,
the drying shrinkage of RCCPs within the first 28 days significantly
increased. As expected, the rate of increasing of the shrinkage strain
was reduced by time. This rate was much less after the age of 56 days.
It is also obvious in Figure 6
that RCCPs with 15% cement have higher drying shrinkage strain at all
early and later ages. Compared to the drying shrinkage values at 90
days, around 40% of the drying shrinkage strain occurred at 7 days after
drying, while it was around 70% at 28 days. According to Troxell et al.
(3030. Troxell, G. E. (1958) Log-time creep and shrinkage tests of plain and reinforced concrete. In ASTM. 58, 1101-1120.
),
near to 25% of the 10-year drying shrinkage was realized at 14 days and
50 to 60% at 90 days and below 80% in 1 year. Pittman reported that the
28-day drying shrinkage of concrete might occur with an average of 40%
of the 20 years shrinkage (4-94.
Pittman, D.W. (1989) The Effects of the Construction Process on
Selected Fresh and Hardened Properties of Roller-Compacted Concrete
(RCC) Pavements. Army engineer waterways experiment station. Vicksburg
Ms Geotechnical Lab. https://apps.dtic.mil/sti/citations/ADA213735.
5. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
6. Cement Concrete and Aggregates Australia (2002) Drying Shrinkage of Cement and Concrete. https://www.ccaa.com.au/iMIS_Prod.
7. Avram, C. (1981) Concrete Strength and Strains, Elsevier Scientific Pub. Co. (1981).
8.
Khayat, K.H.; Libre, N.A. (2014) Roller compacted concrete: field
evaluation and mixture optimization (No. NUTC R363). Missouri University
of Science and Technology. Center for Transportation Infrastructure and
Safety. https://www.semanticscholar.org/paper/Roller-Compacted-Concrete%3A-Field-Evaluation-and-Khayat-Libre/002baa236c54e20a58991d675089cf08233b7fdb.
9. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
).
The mix of 12C with 12% cement content and a coarse to fine aggregate ratio of 1.2 showed the lowest drying shrinkage strain, whereas the mix of 15A with 15% cement content and a coarse to fine aggregate ratio of 0.7 exhibited the highest drying shrinkage strain in most of the periods during the 90 days.
The mix of 12C attained the lowest drying shrinkage strain values after 28 days with 215, 260 and 295 microstrain at 28, 56 and 90 days, respectively. However, at the early ages (before 28 days), the drying shrinkage strain of mix 12C was almost 25% higher than 12A (with 12% cement content and C/F ratio of 0.7). The mix of 12A had the lowest drying shrinkage strain at the early ages until 21 days with 98, 135 and 190 microstrain at 7, 14 and 21 days, respectively. As with 12C, similar trends were observed for 12A, 12B, 12D from 28 days up to 90 days, while the shrinkage values for these mixes were 10% higher than mix 12C on average.
Therefore, it can be concluded that mix 12C might have the lowest drying shrinkage strain in the long term. Pittman and Ragan (99. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
)
reported that an RCC mix with mid-range coarse to fine ratio (around 1)
and optimum moisture content would have the lowest drying shrinkage
strain at 28 days. Zhang et al. (3131.
Zhang, J.; Han, Y.D.; Gao, Y. (2014) Effects of water-binder ratio and
coarse aggregate content on interior humidity, autogenous shrinkage, and
drying shrinkage of concrete. Mater. Civil Engin. 26 [1], 184-189. https://doi.org/10.1061/(ASCE)MT.1943-5533.0000799.
)
demonstrated that increasing coarse aggregate content in concrete
reduces the shrinkage strain. They also reported that the effect of
coarse aggregate on drying shrinkage is considerably higher than
autogenous shrinkage. Adam et al. (3232.
Adam, I.; Sakata, K.; Ayano, T. (2001) Influence of coarse aggregate on
the shrinkage of normal and high-strength concretes. J. Facult. Environ. Sci. Technol. Okayama Univ. 6 [1], 41-45. http://doi.org/10.18926/fest/11529.
)
studied the influence of coarse aggregate on drying shrinkage of
concrete. They reported that using more aggregates caused cement paste
to have a lower drying shrinkage due to elastic deformation of the
aggregate, which leads to restraining of the drying shrinkage of cement
paste. However, Pittman and Ragan (99. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
)
reported that using higher coarse aggregate content along with higher
water content in RCCP might result in higher drying shrinkage. Mehta and
Monteiro (3333. Mehta, P. K.; Monteiro, P. J. (2017) Concrete microstructure, properties, and materials.
) revealed that concrete with higher coarse aggregate content leads to higher elasticity in concrete. According to Neville (3434. Neville, A.M. (1995) Properties of concrete (Vol. 4): Longman London.
), higher elastic modulus in concrete results in lower drying shrinkage. Neville (3434. Neville, A.M. (1995) Properties of concrete (Vol. 4): Longman London.
)
also reported that aggregate is a significant factor affecting
shrinkage in concrete that restrains the shrinkage. The following
equation obviously shows the importance of aggregate volume (Equation [1]):
Where Sc is the shrinkage of concrete, Sp is the shrinkage of the cement paste, a is the volume fraction of aggregate and n is a constant depending on the elasticity of aggregate and varies between 1.2 and 1.7.
On the other hand, incrementing the cement dosage from 12% to 15% led to drying shrinkage increment. The mix of 15A (with 15% cement content and C/F of 0.7) attained the highest drying shrinkage among all non-cured RCCPs, while the drying shrinkage values were 288, 335 and 398 microstrain at 28, 56 and 90 days, respectively. Thus, RCCP with 0.7 C/F and 15% ratio would lead to higher drying shrinkage strain. The RCCP mixes of 15B, 15C and 15D had similar trends in most of the periods with an average drying shrinkage of 350 microstrain at 90 days. However, the average drying shrinkage values for the mix of 15B was almost 10% higher than 15C and 15D from 7 to 28 days. Similar to RCCPs with 12% cement content, the drying shrinkage values had a sharp increment up until 56 days, and afterwards the trends were almost constant up until 90 days.
In total, by
incrementing the cement dosage from 12% to 15%, the drying shrinkage of
RCCPs had almost 20% increment on average. The drying shrinkage strain
had a remarkable increment of 12% when the coarse to fine ratio was
lower than 1.0 for RCCPs with 15% cement content. However, for RCCPs
with 12%, no significant changes were shown. Therefore, it can be
concluded that the RCCPs with 15% cement would tend to exhibit higher
drying shrinkage. According to Pittman and Ragan (99. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
), using higher water content with finer aggregate might induce higher drying shrinkage. Gholami and Modarres (1010.
Gholami, N.; Modarres, A. (2019) Shrinkage behaviour of
superplasticised RCCP and its relationship with internal temperature. Inter. Pave. Engi. 20 [1], 12-23. https://doi.org/10.1080/10298436.2016.1244438.
)
studied the drying shrinkage of superplasticized RCCP and reported that
by adding more water content, the drying shrinkage of RCCP at the early
ages increased significantly.
Jingfu et al. (1111.
Jingfu, K.; Chuncui, H.; Zhenli, Z. (2009) Strength and shrinkage
behaviors of roller-compacted concrete with rubber additives. Mater. Struc. 42 [8], 1117-1124. https://doi.org/10.1617/s11527-008-9447-x.
)
carried out an investigation on rubberized RCCP and demonstrated that
the shrinkage of concrete initiated from cement paste and aggregate
exhibits as a shrinkage restrainer. Carlson (1313.
Carlson, R.W. (1938) Drying shrinkage of concrete as affected by many
factors. American Soc Testing & Materials Proc. 38 [2], 419-437.
) revealed that cement paste, which is not restrained by aggregate, shrinks 5 to 15 times more than PCC. Wongkeo et al. (3535.
Wongkeo, W.; Thongsanitgarn, P.; Chaipanich, A. (2012) Compressive
strength and drying shrinkage of fly ash-bottom ash-silica fume
multi-blended cement mortars. Mater. Des. (1980-2015). 36, 655-662. https://doi.org/10.1016/j.matdes.2011.11.043.
)
demonstrated that cement paste in concrete is usually where drying
shrinkage originates. This is in accordance with Mehta and Monteiro (3333. Mehta, P. K.; Monteiro, P. J. (2017) Concrete microstructure, properties, and materials.
). Bogas et al. (3636.
Bogas, J.A.; Nogueira, R.; Almeida, N.G. (2014) Influence of mineral
additions and different compositional parameters on the shrinkage of
structural expanded clay lightweight concrete. Mater. Des. (1980-2015). 56, 1039-1048. https://doi.org/10.1016/j.matdes.2013.12.013.
)
reported that using a higher volume of water induces higher vapor,
which finally results in a considerable volume change in concrete. They
also demonstrated that when the water and cement content (paste volume)
is higher, the rigidity of concrete might be lower. According to Aslam
et al. (3737.
Aslam, M.; Shafigh, P.; Jumaat, M.Z. (2016) Drying shrinkage behaviour
of structural lightweight aggregate concrete containing blended oil palm
bio-products. Clean. Prod. 127, 183-194. https://doi.org/10.1016/j.jclepro.2016.03.165.
),
the shrinkage of concrete is highly affected by cement paste due to
cement contraction, and the higher water content in concrete eventually
yields considerable volume changes.
3.3.2. Cured condition
⌅Figure 7 indicates the development of drying shrinkage strain of RCCPs for the cured condition. All the specimens were measured immediately after 7 days’ moist curing for the first time up until 90 days. As is clearly shown, similar to the non-cured condition, drying shrinkage strain increased by increasing cement content from 12% to 15% while significant increase was monitored in drying shrinkage strain when the coarse to fine ratio was lower than 1. The drying shrinkage strain decreased when the coarse to fine aggregate ratio decreased to below 1, with an average of 21% and 27% for 12% and 15% cement dosage, respectively.
As the non-cured condition, the mix of 12C had the lowest and the mix of 15A had the highest drying shrinkage strain in the long term, respectively. The drying shrinkage values for the mix of 12C were 198, 242 and 310 microstrain at 28, 56 and 90 days, respectively; while, it was 302, 378 and 427 for 15A, respectively.
The mix of 12A had the
lowest drying shrinkage strain until 20 days with 188 microstrain while
after 20 days the shrinkage values had a significant increase up to 90
days and reached a peak of 390 microstrain at 90 days. The trend and
values for the mixes of 12B and 12D were very close to each other, and
the ultimate drying shrinkage strain was 330 microstrain on average.
Thus, the mix of 12C tends to have the least drying shrinkage strain.
This might be due to the higher aggregate content, more coarse aggregate
than fine aggregate and higher elasticity in this mix, which exhibited
as a shrinkage restrainer in RCCP (11-1311.
Jingfu, K.; Chuncui, H.; Zhenli, Z. (2009) Strength and shrinkage
behaviors of roller-compacted concrete with rubber additives. Mater. Struc. 42 [8], 1117-1124. https://doi.org/10.1617/s11527-008-9447-x.
12.
Hashemi, M.; Shafigh, P.; Karim, M.R.B.; Atis, C.D. (2018) The effect
of coarse to fine aggregate ratio on the fresh and hardened properties
of roller-compacted concrete pavement. Const. Build. Mater. 169, 553-566. https://doi.org/10.1016/j.conbuildmat.2018.02.216.
13.
Carlson, R.W. (1938) Drying shrinkage of concrete as affected by many
factors. American Soc Testing & Materials Proc. 38 [2], 419-437.
), (32-3432.
Adam, I.; Sakata, K.; Ayano, T. (2001) Influence of coarse aggregate on
the shrinkage of normal and high-strength concretes. J. Facult. Environ. Sci. Technol. Okayama Univ. 6 [1], 41-45. http://doi.org/10.18926/fest/11529.
33. Mehta, P. K.; Monteiro, P. J. (2017) Concrete microstructure, properties, and materials.
34. Neville, A.M. (1995) Properties of concrete (Vol. 4): Longman London.
). Kovler and Jensen (3838. Kovler, K.; Jensen, O.M. (2007) Internal curing of concrete. RILEM publications SARL.
)
studied aggregate replacement in lightweight aggregate and demonstrated
that by increasing the volume of aggregate replacements, the fraction
of paste would be increased.
On the other hand, RCCPs with 15% cement content had higher drying shrinkage strain. The mix of 15A attained the highest drying shrinkage values during almost every period, and the shrinkage values were 302, 378 and 427 microstrain at 28, 56 and 90 days, respectively. Therefore, the RCCP that has 15% cement content with a coarse to fine ratio of 0.7 would have higher drying shrinkage strain.
For the mixes 15B, 15C and 15D, the shrinkage
values were very close to each other, and the ultimate drying shrinkage
strain was 335 microstrain on average. Therefore, mix 15A would attain
higher drying shrinkage strain. This might be for two major reasons. The
first reason is higher usage of fine aggregate content, which led to
lower elasticity in concrete and higher drying shrinkage strain (3434. Neville, A.M. (1995) Properties of concrete (Vol. 4): Longman London.
, 3535.
Wongkeo, W.; Thongsanitgarn, P.; Chaipanich, A. (2012) Compressive
strength and drying shrinkage of fly ash-bottom ash-silica fume
multi-blended cement mortars. Mater. Des. (1980-2015). 36, 655-662. https://doi.org/10.1016/j.matdes.2011.11.043.
). The second reason is higher paste volume, which resulted in higher shrinkage (35-3735.
Wongkeo, W.; Thongsanitgarn, P.; Chaipanich, A. (2012) Compressive
strength and drying shrinkage of fly ash-bottom ash-silica fume
multi-blended cement mortars. Mater. Des. (1980-2015). 36, 655-662. https://doi.org/10.1016/j.matdes.2011.11.043.
36.
Bogas, J.A.; Nogueira, R.; Almeida, N.G. (2014) Influence of mineral
additions and different compositional parameters on the shrinkage of
structural expanded clay lightweight concrete. Mater. Des. (1980-2015). 56, 1039-1048. https://doi.org/10.1016/j.matdes.2013.12.013.
37.
Aslam, M.; Shafigh, P.; Jumaat, M.Z. (2016) Drying shrinkage behaviour
of structural lightweight aggregate concrete containing blended oil palm
bio-products. Clean. Prod. 127, 183-194. https://doi.org/10.1016/j.jclepro.2016.03.165.
).
In
total, as with the non-cured condition, the increase of water and
cement content showed an increment in drying shrinkage with an average
of 6%. This is because of higher paste volume (conversely less aggregate
content). Neville (55. Neville, A.M. (1995) Properties of concrete (Vol. 4). London: Longman.
)
revealed that two significant factors that affect drying shrinkage in
concrete are aggregate content and water content (initial moisture) and
reported that the loss of adsorbed water yields most of the changes in
concrete volume, while loss of free water derives little or no
shrinkage. Basma and Jawad (3939. Basma, A.A.; Jawad, Y.A. (1995) Probability model for the drying shrinkage of concrete. Mater. 92 [3], 246-251. https://doi.org/10.14359/1116.
) reported that the rate of water loss in concrete affects the drying shrinkage strain of concrete. Day et al. (4040. Siegel, J.A.; Mirakovits, J.A.; Hudson, B. (2013) Concrete mix design, quality control and specification. CRC Press. https://doi.org/10.1201/b15624.
)
revealed that the drying shrinkage of concrete is more influenced by
adding more water when concrete is in its fresh state. Aslam et al. (3737.
Aslam, M.; Shafigh, P.; Jumaat, M.Z. (2016) Drying shrinkage behaviour
of structural lightweight aggregate concrete containing blended oil palm
bio-products. Clean. Prod. 127, 183-194. https://doi.org/10.1016/j.jclepro.2016.03.165.
) demonstrated that by decreasing the water content in concrete, the drying shrinkage of the concrete will be decreased more.
In
conclusion, the average drying shrinkage strain in non-cured and cured
conditions were around 330 and 350 microstrain at 90 days, respectively.
According to the literature, the drying shrinkage of RCCP is less than
PCC with a maximum of 400-500 microstrain (88.
Khayat, K.H.; Libre, N.A. (2014) Roller compacted concrete: field
evaluation and mixture optimization (No. NUTC R363). Missouri University
of Science and Technology. Center for Transportation Infrastructure and
Safety. https://www.semanticscholar.org/paper/Roller-Compacted-Concrete%3A-Field-Evaluation-and-Khayat-Libre/002baa236c54e20a58991d675089cf08233b7fdb.
)
while the drying shrinkage of normal concrete is reported to range
between 200 and 1200 microstrain due to its ingredient and mix
proportion (99. Pittman, D.W.; Ragan, S.A. (1998) Drying shrinkage of roller-compacted concrete for pavement applications. Mater. Jour. 95 [1], 19-26. https://doi.org/10.14359/348.
).
However,
the effect of curing could not be neglected. While curing contributed
to attaining lower drying shrinkage at the early ages, for the long
term, curing led to higher drying shrinkage strain. Aslam et al. (3737.
Aslam, M.; Shafigh, P.; Jumaat, M.Z. (2016) Drying shrinkage behaviour
of structural lightweight aggregate concrete containing blended oil palm
bio-products. Clean. Prod. 127, 183-194. https://doi.org/10.1016/j.jclepro.2016.03.165.
) revealed that curing yields lower drying shrinkage at the early ages. On the contrary, Carlson (1313.
Carlson, R.W. (1938) Drying shrinkage of concrete as affected by many
factors. American Soc Testing & Materials Proc. 38 [2], 419-437.
)
reported that curing in concrete led to higher shrinkage. However,
there is a necessity to carry out a comprehensive investigation on the
curing effect on the drying shrinkage of RCCP.
In this study, it
was found that RCCP with 1.2 C/F ratio and 12% cement content not only
achieved the least drying shrinkage strain in both cured and non-cured
conditions, but also, with regard to the results for fresh and
mechanical properties (section 3.1 & 3.2), the mix of 12C had the
appropriate properties. This is in accordance with Hashemi et al. (1212.
Hashemi, M.; Shafigh, P.; Karim, M.R.B.; Atis, C.D. (2018) The effect
of coarse to fine aggregate ratio on the fresh and hardened properties
of roller-compacted concrete pavement. Const. Build. Mater. 169, 553-566. https://doi.org/10.1016/j.conbuildmat.2018.02.216.
),
who recommended a mixture with 12% cement content and a coarse to fine
aggregate ratio of 1.2 to achieve a workable, high-strength and durable
RCCP.
However, it is obvious that the other parameters that might affect the drying shrinkage of RCCP need to be investigated comprehensively.
3.3.3. Comparison with prediction models
⌅
Table 2
shows the list of models and related equations that were used in this
study for predicting the ultimate drying shrinkage strain of RCCPs.
Three prediction models were ACI 209.2 R-08, Bazant-Baweja B3 and GL2000
(4141.
Videla, C.; Carreira, D.J.; Garner, N. (2008) Guide for modeling and
calculating shrinkage and creep in hardened concrete. ACI report, 209.
).
Model name | Equations | Note |
---|---|---|
ACI 209.2 R-08 (4141.
Videla, C.; Carreira, D.J.; Garner, N. (2008) Guide for modeling and
calculating shrinkage and creep in hardened concrete. ACI report, 209. ) |
|
|
Bazant-Baweja B3 (4141.
Videla, C.; Carreira, D.J.; Garner, N. (2008) Guide for modeling and
calculating shrinkage and creep in hardened concrete. ACI report, 209. ) |
| |
GL2000 (Gardner 2004) (4141.
Videla, C.; Carreira, D.J.; Garner, N. (2008) Guide for modeling and
calculating shrinkage and creep in hardened concrete. ACI report, 209. ) |
The ultimate drying shrinkage for Bazant-Baweja B3 and GL2000 models is provided by the related equations in Table 2 while the ACI 209.2 R-08 prediction model required the ultimate drying shrinkage to achieve the drying shrinkage development during the time. With regard to the literature, Neville reported that the 28-day drying shrinkage is almost 40% of the 20-year shrinkage. Therefore, the 28-day drying shrinkage strain was used to compare with the data carried out in this study.
Figure 8 and Figure 9 show the comparison of drying shrinkage strain in this study among the prediction models, which are calculated by the average in both cured and non-cured conditions at 1, 7, 14, 28, 56 and 90 days.
As is clear, in both curing conditions the drying shrinkage strain provided by both ACI 209.2 R-08 and Bazant-Baweja B3 is lower than the measured shrinkage in this study by an average of 46% and 21%, respectively, while the average drying shrinkage strain that is provided by GL2000 in both curing conditions is 50% higher than the measured RCCPs on average. In total, the Bazant-Baweja B3 and GL2000 models had the lowest and highest difference with the measured drying shrinkage, respectively. Furthermore, Bazant-Baweja B3 gave the best prediction for drying shrinkage strain at the early ages with 17% and 19% difference with the measured RCCPs at 7 and 28 days, respectively.
4. CONCLUSIONS
⌅This study was performed to investigate the effect of coarse to fine aggregate ratios on the drying shrinkage of roller compacted concrete pavement (RCCP) by providing eight mix proportions: four different coarse to fine aggregate ratios (0.7, 1, 1.2 and 1.5) and two cement dosages (12% and 15% of total dry solid mass). The drying shrinkage development was monitored in both cured and non-cured conditions, and measurements commenced once the specimens were demolded for up to 90 days. In addition, the fresh and hardened properties of RCCPs were carried out. The study may have resulted in following conclusions:
Increasing the coarse to fine aggregate ratio from 0.7 to 1.5 for RCCPs, which contained 12% and 15% cement content, led to an increment in Vebe time values by 50% and 60%, respectively.
Increasing the coarse to fine aggregate ratio from 0.7 to 1.2 led to increments in the strengths of compressive, splitting tensile and flexural tensile of about 21%, 17% and 19%, respectively. However, by increasing the coarse to fine aggregate ratio from 1.2 to 1.5, those strengths decreased by around 14%, 7% and 9%, respectively.
For both RCCPs with 12% and 15% cement contents, the compressive, splitting tensile and flexural tensile strengths reached the peak of the strengths at a coarse to fine aggregate ratio of 1.2.
In non-cured condition, around 40% of the entire drying shrinkage strain occurred in the first 7 days after drying, while it was around 70% in the first 28 days. In this condition, the highest and lowest drying shrinkage strain was recorded at 90 days with about 400 microstrain (mix 15A) and 300 microstrain (mix 12C), respectively. While, in cured condition, they were recorded as 430 microstrain (mix 15A) and 310 microstrain (mix 12C), respectively.
In both cured and non-cured conditions, the drying shrinkage strain increased by increasing the cement content from 12% to 15%. In addition, a significant increase was monitored in the drying shrinkage strain when a coarse to fine aggregate ratio lower than 1.0 was used. Therefore, it is recommended to use more coarse aggregate than fine aggregate in the RCCP mixtures.
By considering test results of fresh and mechanical properties, it is recommended to use a coarse to fine aggregate ratio in the range of 1.0 to 1.2 in RCCP mixture.
Bazant-Baweja B3 had the best prediction for drying shrinkage strain of RCCPs compared to ACI 209.2 R-08 and GL2000.