A Vision To Clear Solutions.
Before doing the comparison study lets know what these terms mean.
CPCC –Cement-Polymer Composite Coated Rebars
FBEC – Fusion Bonded Epoxy Coated Rebars
CRSD – Corrosion Resistant Steel Deformed Rebars
CPCC –Cement-Polymer Composite Coated Rebars
FBEC – Fusion Bonded Epoxy Coated Rebars
CRSD – Corrosion Resistant Steel Deformed Rebars
1.0
Corrosion Control of Reinforcement bars (Rebars)
40% of failure of structures is on account of corrosion of embedded steel
reinforcement in concrete. Therefore corrosion control of steel reiorcement is
a subject of paramount importance.First and foremost for corrosion control is
the good quality of concrete through good construction practices.
2.0 Cement-Polymer Composite Coated Rebars (CPCC)
System at a glance
System at a glance
Products involved in CPCC normally are:
• De-rusting Solution
• Alkaline Powder
• Phosphating Jelly
• Inhibitor Solution
• Sealing Solution
• De-rusting Solution
• Alkaline Powder
• Phosphating Jelly
• Inhibitor Solution
• Sealing Solution
|
S No
|
Parameter
|
Requirement
|
|
1.
|
Pre-treatment
(Surface reparation) |
Sand
blasting to the near white metal
|
|
2.
|
Primer
Coat
|
To be
given within 4 hours of sand blasting.
|
|
3.
|
Sealer
Coat
|
Within
30 minutes of primer coat, this should be given. Thickness 150 microns plus
minus 25 microns.
|
|
4.
|
Air
curing
|
Six
hours before use in the work.
|
|
5.
|
Continuity
of coating
|
No
defects such as cracking, bulging, peeling, no rust mark. Inspect visually.
|
|
6.
|
Adhesion
of coating – test
|
Coated
bars are bent at 120 o around a mandrel. NO peeling or
cracking should be observed on outer radius.
|
|
7.
|
Stacking
|
Stack
bars on buffer material.
|
|
8.
|
Cutting
, bending, welding
|
Coat
bars can be cut and bent. Cut ends and weld positions should be treated with
same formulation.
|
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This system has been developed mainly as a factory / shop process.
• The approach behind development of this system is that the base metal of rebars, contains ? electrons which get readily released in corrosive environment leading to oxidation of iron and thereby formation of Ferrous Oxide (II) (rust) as principal deterrent.
• The approach behind development of this system is that the base metal of rebars, contains ? electrons which get readily released in corrosive environment leading to oxidation of iron and thereby formation of Ferrous Oxide (II) (rust) as principal deterrent.
• In order to
prevent this oxidation a surface coating capable of interacting/nullifying the
released electrons is provided.
• Further
pre-stressing and reinforcing steel, in concrete during service life, are
exposed to an alkaline environment and this necessitates introductions of a top
coat which should be compatible to primer and alkaline environment.
3.0 Fusion Bonded Epoxy Coated Rebars (FBEC)
System at a glance
System at a glance
|
No.
|
Parameter
|
Requirement
|
|
1.
|
Pre-treatment
(Surface reparation) |
1. Bars
are first cleaned from surface contamination
such as oil, grease etc. by chemical process before shot blasting.
2. The
reinforcement bars are cleaned by shot blasting or
grit blasting to white or near white stage.
3. The
blast cleaned bars are then heated through
induction heaters at preset temperature level around 230°C. |
|
2.
|
Coating
|
Hot
bars are then fed to the coating booth, where the
epoxy powder is sprayed electrostatically. |
|
3.
|
Curing
and Cooling
|
Coated
bars are then cured and forced
cooled by water spraying to enable handling and testing. |
|
4.
|
Continuity
of coating
|
On line
and off line holiday checks, thickness checks are carried out. The adhesion
of the coated bars is also tested frequently by bending of the bar.
|
|
5.
|
Testing
of Performance of
rebar
|
Various
other tests are performed in laboratory like chemical resistance, short
spray, resistance in continuance boiling water, abrasion resistance and
impact resistance etc. These are conducted on every batch of production.
|
|
6.
|
Handling
& Stacking
|
Fusion
Bonded Epoxy Coated Bars require padded contacts during transportation,
stacking, handling and till the concreting is done.
|
|
7.
|
Cutting,
bending & welding
|
The cut
ends, welded spots and handling damages are required to be repaired with
special liquid epoxy compatible with the coating material as per
specification of the coating agency.
|
• Fusion bonded
epoxy is basically 100% solid finely ground fused powder particles, which when
heated; melt to form a continuous adherent film.
• There is no
passivating primer film provided in case of FBEC rebars.
• This coating
introduces a medium of weakness in the path of an intimate bond between rebar
and alkaline concrete.
• Extensive
investigation carried out on 40 bridges in Florida Key in USA has revealed that
disbandment can occur easily in the FBEC rebars which lacked passivation layer
of Ferrous oxide (II) and is a precursor to corrosion.
• Higher
co-efficient of Thermal Expansion of fusion bonded epoxies impose large thermal
stresses in epoxy coating leading to its early failure.
Epoxy coats the rebar in the following manner:
Melts
Flows
Gels
Cures
Cools
Adheres as coating
Melts
Flows
Gels
Cures
Cools
Adheres as coating
4.0 Corrosion Resistant Steel Deformed Rebars (CRSD)
• Mechanism of resistance to corrosion begins with the formation of initial layer of protective oxide or rust. (Hypo oxides). Unlike common rust on normal rebars, the CRSD rust is passive, tenacious and self-renewing.
• Mechanism of resistance to corrosion begins with the formation of initial layer of protective oxide or rust. (Hypo oxides). Unlike common rust on normal rebars, the CRSD rust is passive, tenacious and self-renewing.
• The protective
oxide is fine textured, tightly adherent and a barrier to moisture, oxygen,
carbon dioxide, Sulphur dioxide and chloride effectively preventing further
corrosion.
• Scale on normal
bars of steel is coarse textured flaky oxide that does not prevent moisture or
oxygen from reaching the underlying bars and continuing the corrosion.
• As corrosion
resistance is in the chemistry of the grade, if the passive oxide layer gets
removed somehow, a new passive layer is formed immediately.
|
CRSD –
Mechanical Properties
|
||
|
Properties
|
IS:1786
Fe500D
|
CRSD
|
|
Yield
Stress, YS (min, N/mm2)
|
500
|
500
|
|
%
Elongation
|
16
|
16
|
|
Ultimate
Tensile Strength, UTS (min, N/mm2)
|
565
|
580
|
5.0 Comparison (CPCC – FBEC – CRSD)
|
Parameters
|
CPCC
|
FBEC
|
CRSD
|
|
Thickness
of Coating
|
175 mm
– 300 mm
|
300 mm
– 675 mm
|
No
coating required
|
|
Type of
Protection to rebar
|
Extrinsic
|
Extrinsic
|
Intrinsic
|
|
Pre-treatment
|
Pretreatment
is required before coating
|
Pretreatment
is required before coating
|
No
pre-treatment required
|
|
Treatment
to surface
|
Before
coating the surface made little rough when some damage is introduced.
|
Before
coating the surface made little rough when some damage is introduced.
|
The
surface of the finished good is not disturbed or damaged at all.
|
|
Temperature
treatment
|
The
whole process is done at room temperature.
|
230°C –
400°C
|
No
treatment required
|
|
Special
Bending requirement
|
Modified
mandrel diameter is specified by Indian Standard
|
Modified
mandrel diameter is specified by Indian Standard
|
Same as
other TMT rebars of Fe 500D grade
|
|
Defects
introduced
|
Holiday
Effect
|
Holliday
Effect
|
Nil
|
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