CONCEPT OF CURING
Curing is the process for maintaining moisture in concrete within a
reasonable temperature range and following placement so that the concrete’s
designed properties can develop. Curing
is also a key player in mitigating cracks in the concrete, which severely
impacts durability. Cracks allow open access for harmful materials to bypass
the low permeability concrete near the surface. Good curing can help mitigate
the appearance of unplanned cracking. Curing influences the concrete’s
ultimate durability, strength, water tightness, abrasion resistance, volume
stability and resistance to freeze / thaw cycles and dicing salts. These
properties are reduced significantly when curing is inadequate. As per ACI 308
The term “curing” is frequently used to describe the process by which
hydraulic-cement concrete matures and develops hardened properties over time as
a result of the continued hydration
of the cement in the presence of sufficient water and heat. The term
“curing” is also used to describe the action taken to maintain moisture and
temperature conditions in a freshly placed cementitious mixture to allow hydraulic-cement
hydration and, if applicable, pozzolanic reactions to occur so that the
potential properties of the mixture may develop (ACI 116R and ASTM C 125). (A
mixture is properly proportioned and adequately cured when the potential
properties of the mixture are achieved and equal or exceed the desired
properties of the concrete.)
NECESSECITY OF CURING
When an ordinary portland cement(OPC) is mixed with water, a chemical
reaction called hydration which is exothermic in nature takes place. As cement
hydrates, the strength, durability and density of the concrete increases. The
more complete the hydration, the higher these properties become. Complete
hydration of cement takes a very long time. The hydration process is far from
over when the surface of the concrete is hard. Theoretically, the hydration
process continues for years. With sufficient water, the hydration process will
be approximately 30% complete in 3 days, 60% complete in 7 days and 98%
complete in 28 days.Most freshly mixed concrete contains more water than is
required to hydrate the cement in the mix. Water loss in the first few days due
to bleed water and evaporation reduces the water content of the mix and slows
or stops the hydration process.
It is critical to the long term durability of the concrete that water
evaporation be minimized. Excess loss of water causes the concrete to shrink,
creating tensile stresses within the concrete. If these stresses develop before
the concrete achieves adequate tensile strength, surface cracking results. The
hydration can proceed only in saturated space, the total water requirement for
cement hydration is “about 0.44 g of water per gram of cement,( Other sources
place this approximate value at 0.42 to 0.44 g of water for each gram of dry
cement (Powers 1947; Taylor 1997; Neville 1996))plus the curing water that must
be added to keep (the capillary pores of) the paste saturated” (Powers 1948).In
concrete technology this water called as gel water because these water acts
like a carrier for the CSH gel. The curing of the concrete should be done after
the placing and finishing work completed. For mixtures with a low to zero
bleeding rate, or in the case of aggressively evaporative environments, or
both, surface drying can begin well before initial set and well before
initiation of finishing operations, Under such conditions, it is necessary to
reduce moisture loss by one or more initial curing techniques, such as fogging,
the use of evaporation reducers, or by modifying the environment with
sunshades, windscreens, or enclosures. When the
conclusion of finishing operations coincides with the time of final set as
indicated in fig 4(a), final curing is applied at exactly the right time to
reduce the peak rate of moisture loss. A delay in final curing can result in
considerable water loss (Al-Fadhala and Hover 2001). For mixtures with a low to zero bleeding rate, or in the
case of aggressively evaporative environments, or both, surface drying can
begin well before initial set and well before initiation of finishing
operations, as indicated in Fig. 4(b). Under such conditions, it is
necessary to reduce moisture loss by one or more initial curing techniques,
such as fogging, the use of evaporation reducers, or by modifying the environment
with sunshades, windscreens,
THE CURING PROCESS
The water is held in concrete two primary ways:
1. Wet curing the concrete by keeping it constantly wet for
a minimum of 7 days. This is done by ponding, immersion, spraying or fogging,
or applying saturated wet coverings such as burlap.
2. Sealing the surface of the fresh concrete to prevent
water from leaving. Typical methods include covering the concrete with
impervious paper or plastic sheets or by applying a curing compound to form a
membrane on the surface. Each curing method has advantages and disadvantages.
The method or combination of methods used may depend on availability, size and
shape of the concrete, the location, environment or economics.
Wet curing by flooding the surface continuously with water is the best
way to cure concrete. To be effective, wet curing must last at least 7 days. It
is important that the concrete not be allowed to dry between soakings.
Alternate wetting and drying of the surface actually damages the concrete.
Membrane curing is the most common method of curing new concrete. Curing compounds
can be waxes, resins, chlorinated rubbers, styrene acrylics or epoxies.
Advantages of using a curing compound over moist curing include ease of
application, cost effectiveness and the extended curing action provided beyond
the 7 days required for wet curing.
Curing compounds and so-called “breathable sealers” meeting the
requirements of ASTM C 309 and C 1315, permit moisture transmission and have a
variable capacity to retard moisture loss, depending
on the quality of the product used, field application, and field
conditions.
TYPE OF CURING COMPOUNDS
Liquid membrane-forming compounds are classified according to the colour
of the compound and the type of solid constituent present for forming the membrane.
Table 1 shows the American Society for Testing and Materials (ASTM) C 309 and
American Association of State Highway 3 and Transportation Officials (AASHTO) M
148 classifications for membrane-forming compounds. The ASTM and AASHTO
classifications are equivalent. Membrane forming curing compounds is of two
general types; clear or white pigmented. Clear curing compounds may contain a
fugitive dye (usually red) that makes it easier to visually check for complete
covering of the concrete surface when the compound is applied. The dye will
fade after several days. White pigmented curing compounds have the added
benefit of light reflectivity to aid in keeping the concrete cool improving the
hydration process.
All the resin based curing compounds confirming to ASTM C309 class B can also
be tested as per BS 7542-1992. High efficiency Polymer based film forming curing agent and 90% or
greater curing efficiency when tested to BS 7542-1992. The properties and use of Liquid Membrane-forming Curing
Compounds are also described in AS 3799.
Membrane-forming curing compounds that meet the requirements of ASTM C
309 permit the loss of some moisture and have a variable capacity to reduce
moisture loss from the surface, depending on field application and ambient
conditions (Mather 1987, 1990; Shariat and Pant 1984; Senbetta 1988). Compounds
formulated to meet the requirements of ASTM C 1315 have special properties,
such as alkali resistance, acid resistance, adhesion-promoting qualities, and
resistance to degradation by ultraviolet light, in addition to their moisture retention
capability as measured by ASTM C 156. Products meeting the requirements of ASTM
C 1315 are often referred to as “breathable membrane
sealers” after they have performed the function of a curing membrane
used during the final curing. When these products are tested in accordance with
ASTM C 156, the allowable moisture loss is 0.40 kg/m2 (0.08 lb/ft2) in 72 h
when applied at a curing compound coverage rate of 5.0 or 7.4 m2/L (200 or 300
ft2/gal.) for Type I or Type II compounds, respectively. When performing the
ASTM C 156 test in a laboratory to verify compliance with either ASTM C 309 or
C 1315, the surface of the test specimen is relatively smooth, and the laboratory-applied
coverage rates specified in the test method
can
be readily obtained. ASTM C 1315 notes that agencies can require a
substantially greater application rate on deeply textured surfaces. Further,
the specified evaporative environment for the ASTM C 156 test corresponds to an
evaporation rate from a free water surface varying between about 1/2 to 1
kg/m2/h (0.1 to 0.2 lb/ft2/h), which may be less severe than encountered in a
given construction environment. For these reasons, the water loss experienced by
concrete in the field may vary from the values specified by ASTM for compliance
with the requirements of C 309 or C 1315.
Curing materials can be composed of wax or other organic material
thinned with a solvent. The solvent can make the use of the curing compound
subject to various restrictions or regulations governing the transport,
storage, or use of hazardous materials. When appropriate, adequate ventilation
should be provided and other safety precautions should be taken when using
solvent- based compounds. Other similar curing compounds based on water-soluble
solids or a water emulsion are available. When the concrete surface is to
receive paint, finishes, or toppings that require positive bond to the
concrete, it is critical that the curing procedures and subsequent coatings,
finishes, or toppings be compatible to achieve the necessary bond. It should be
noted that all water-based products appear white when first applied. Unless
they include a white pigment such as titanium dioxide, all water based curing
compounds will dry clear. Water based cures require soap and water clean-up
while solvent based materials require mineral spirits. It is important to not
mix solvent-based and water based cures. Most applicators who apply both types
will have different spray equipment for each type to avoid the extensive clean
out required when switching from one type to the other. Curing compounds
meeting the requirements of ASTM C 1315 have been formulated to promote such
adhesion, and ASTM C 1315 includes references to test methods for evaluating
the bonding of tile and other floor coverings. Testing to establish
compatibility among the curing compound, subsequent surface treatments,
concrete moisture content, and the actual finished surface texture of the
concrete is recommended when performance is critical. Such testing is beyond
the scope of this document, but useful references include Suprenant and Malisch
(1998d,1999a,b).In FOSROC Range there are many curing compound like Concure WB
is a white, low viscosity wax emulsion which incorporates a special alkali
reactive emulsion breaking system. This system ensures that the emulsion breaks
down to form a non penetrating continuous film immediately upon contact with a
cementitious surface. This impervious film prevents excessive water evaporation
which in turn permits more efficient cement hydration, thus reducing shrinkage
and increasing durability. Once formed, the membrane will remain on the
concrete surface until eventually broken down and eroded by natural weathering.
Where it is required to apply a further treatment to such concrete surface, it
may be necessary to remove the membrane remaining after curing by wire brushing
or other mechanical means. The use of curing membranes on internal floor slabs
is generally to be avoided where additional surface finishes are to be applied.
Concure WB is however ideal where the concrete surface of a floor slab is to be
left as 'finished'.This concure WB complies to ASTM C309-90 Standards. Concure 1315 is an acrylic polymer based
non-degrading, single component, clear curing compound. It is also suitable for
use as a sealer and dust proofer for floors and walls.Concure 1315 is resistant
to UV, abrasion and a range of chemicals. Concure 1315 is applied by spray at a
coverage rate of 5- 10m²/litre. Complies
to ASTM C1315 Type 1, class A. Concure LP90
concrete curing compound is polymer resin based continuous film forming curing
compound and is supplied in various pigmented grades. Clear: Straw liquid
curing to a clear film and Blue: As clear grade but with blue fugitive dye with
Specific Gravity : 0.82 - 0.85 .When first applied to a fresh cementitious
surface the product forms a continuous, non-penetrating coating. This coating dries
to a form a continuous film which provides a barrier to moisture loss ensuring
more efficient cement hydration, improved durability and reduced shrinkage. All
grades of Concure LP90 give 90% or greater curing efficiency when tested to BS
7542-1992.
CALCULATION OF CURING EFFICIENCY
Effectiveness of the curing compound is remarkable dependent on their application,
time and generic type. Curing efficiency (E) of curing can be determined by the
following equation (Cabrera et al, 1989)
Where, k1 = studied property of a non-cured specimen, k2 = studied
property of a specimen cured by the method being evaluated, and k3 = studied
property of water-cured specimen till age of testing. If the curing method is
equally good as water-curing (k2 = k3 ) then the value of E =100%, while for
poor curing method ( k2 > k3 ) the value of E tends to 0%. This definition
gives a convenient scale with which to assess the efficiency of chemical curing
compounds or traditional methods (Cabrera et al, 1989). This concept of
analysis was adopted in this study to investigate the various factors that could
affect the efficiency of water based curing compound(WBCC) applied at OPC
concrete cast-surface, e.g. time of application of WBCC and presence of
blending materials in OPC mixes.
PROPER APPLICATION METHODOLOGY OF CURING COMPOUND
In accordance with the manufacturer recommendations, liquid
membrane-forming curing compounds should be stirred or agitated before use and
applied uniformly at the manufacturer’s recommended rate. The curing compound should
be applied in two applications at right angles to each other to ensure uniform
and more complete coverage. On very deeply textured surfaces, the surface area
to be treated can be at least twice the surface area of a trowelled or floated surface
(Shariat and Pant 1984). In such cases, two separate applications may be
needed, each at 5 m2/L (200 ft2/gal.), with the first being allowed to become
tacky before the second is applied. A curing compound can be applied by hand or
power sprayer, using appropriate wands and nozzles with pressure usually in the
range of 0.2 to 0.7 MPa (25 to 100 psi). If the job size is large, application
by power sprayer is preferred because of speed and uniformity of distribution.
For very small areas such as repairs, the compound can be applied with a wide,
soft-bristled brush or paint roller. Application rates are most readily
verified by recording the number of containers of compound used, or the number
of sprayer tanks or buckets of compound applied to the surface. When the
evaporation rate exceeds the rate of bleeding of the concrete, the surface will
appear dry even though bleeding is still occurring. Under such conditions,
finishing the concrete or the application of curing compound, or both, can be
detrimental because bleed water can be consequently trapped just below the
concrete surface. Clearly identifying this condition in the field is difficult,
and it is always risky to delay finishing and curing. In such cases where it is
important to diagnose this problem, a transparent plastic sheet can be placed
over the unfinished, uncured concrete to shield the test area from evaporation,
and any bleed water can be seen accumulating under the plastic. Another
consequence of applying curing compound to a freshly cast concrete surface that
appears dry is that evaporation will be temporarily stopped, but bleeding might
continue, resulting in map cracking of the membrane film with the subsequent
reduction in moisture-retention capability. This situation would require
reapplication of the curing compound. When using curing compounds to reduce
moisture loss from formed surfaces, the exposed surface should be wetted immediately
after form removal and kept moist until the curing compound is applied. The
concrete should be allowed to reach a uniformly damp appearance with no free
water on the surface, and then application of the compound should begin at
once. As with flatwork, dampening the concrete prevents absorption of the
curing compound, which would prevent the formation of a membrane.
HOW TO CHOOSE A GOOD CURING COMPOUND
While ASTM C-309 is the accepted standard for the curing compound, As
per the standard some materials can retain much more water in the concrete than
others. Generally, the level of solids in the cure affects the thickness of the
film and its effectiveness as a vapour barrier. The higher the solids, the
thicker the film, the more moisture the film will hold in the concrete. A
minimum 15% solids is usually required to pass ASTM C-309. Other common solids
levels for curing compounds like Concure 1315 are contain more than 30% solids.
Be sure that any curing compound used is manufactured by a reputable company
and passes ASTM C-309 or ASTM C-1315. These specifications set a maximum on the
amount of moisture that can be transmitted through a curing compound. If in
doubt, ask the manufacture to provide written certification that the curing
compound passes ASTM C-309 or the cure & seal passes ASTM C-1315.Consider
the application environment to determine if a water based material is more
suitable than a solvent type. If final appearance is important, choose a clear,
non-yellowing material such as a pure acrylic. Materials such as linseed oil,
chlorinated rubber and styrene are excellent curing materials and are cost
effective but they will discolour with continued exposure to ultraviolet light.
This is particularly important when choosing a longer lasting cure & seal
product. When placing pavement, parking decks, curbing, sidewalks, mass
concrete or mat foundations, a white pigmented curing compound is usually
specified. Select a compound that stays in suspension with little agitation and
one that will not clog sprayers. Use only pre-approved, Department Of Transportation(DOT)
tested materials on state projects.
HOW LONG WILL A CURING COMPOUND LAST ON THE SURFACE?
Most curing compounds are designed to last on the surface for a minimum
of 28 days. As stated above curing & sealing compounds like may remain on
the surface much longer. When the concrete is to be eventually treated with
another product such as a penetrating sealer or any resin coating, the curing
compound must be removed(Except Concure 1315) before these products are
applied. Some curing compounds are described as dissipating resins. These
products are designed to readily break down in 28 days. The degree to which
they disintegrate is dependent on their exposure to ultraviolet light and
abrasion.
CONCLUSION
“Curing techniques and curing duration significantly affects curing
efficiency” Various degree of efficiency can be achieved by various in situ-curing
methods. The effectiveness of the concrete curing
method depends on the material used, method of construction and the
intended use of the hardened concrete. Techniques used in concrete curing are mainly
divided into two groups namely, Water adding techniques and Water- retraining
techniques. Curing compounds namely, acrylic and water based are effective in
decreasing plastic and drying shrinkage strain for both ordinary and blended cements
and the curing efficiency of such compounds with respect to compressive
strength are in the range of 84 to 96 percent [Al-Gahtani, 2010] G.E. Abdelaziz
investigated the effect of application time of water based curing compound on strength,
hardness, sorptivity and porosity of blended concrete. His study revealed that
application of WBCC in the early stage (within first 2 hours of casting) would
yield best possible properties of concrete. The time of application of WBCC and
prewater curing had a greater effect on the durability properties of the
concrete (sorptivity and porosity) than on mechanical properties (strength and hardness).
Conventional water curing is the most efficient method of curing as compared to
Membrane curing, Self-curing, Wrapped curing and Dryair curing methods. Using
Membrane curing and Self-Curing methods one can achieve 90% of efficiency as compared
to Conventional Curing method.
REFERENCES
- ACI 308
- ASTM C-309
- ASTM C-1315
- ASTM C 156
- AASHTO M 148
- Identification of Compliance Testing Method for Curing Effectiveness By Seongcheol Choi and Moon Won(February 2008, Rev. June 2008)
- A Review of the Curing Compounds and Application Techniques Used by the Minnesota Department of Transportation For Concrete Pavements By Julie M. Vandenbossche, P.E. November 1999
- A Study of the Effectiveness of PCC Curing Compounds By Nancy M. Whiting and Mark B. Snyder, Ph.D., P.E.,
- A STUDY ON THE INFLUENCE OF CURING ON THE STRENGTH OF A STANDARD GRADE CONCRETE MIX By M.V. Krishna Rao, P. Rathish Kumar, Azhar M. Khan(UDC 666.942.3/.7:691.32:620.175/.176(045)=111)
- Curing Of High performance concrete for strength By N.J.Carino and K.W.Meeks September 2000
- EFFECT ON CONCRETE BY DIFFERENT CURING METHOD AND EFFICIENCY OF CURING COMPOUNDS – A REVIEW ,Nirav R Kholia, Prof. Binita A Vyas, Prof. T. G. Tank,( Kholia et al., International Journal of Advanced Engineering Technology E-ISSN 0976-3945)
- EFFECT OF APPLICATION TIME OF WATER-BASED CURING COMPOUND ON STRENGTH, HARDNESS, SORPTIVITY AND POROSITY OF BLENDING CONCRETES By G. E. ABDELAZIZ
