Types of steel
• Hot rolled bars
1. Hot rolled plain round mild steel bars (MS)
2. Hot rolled ribbed mild steel bars (Not recommended)
3. Hot rolled high strength deformed bars (HYSD)
4. Thermo mechanically treated (TMT)
• Hot rolled cold twisted deformed bars like tor steel
• Hard drawn steel wire fabric
• Check the material test certificate (MTC)
• Yield strength
• Ultimate tensile strength
• Elongation
• Bend test and reverse bend test
Requirements as per IS 1786
Property
|
Fe 415
|
Fe 500
|
Yield strength
|
415 N/mm2
|
500 N/mm2
|
Ultimate tensile strength
|
485 N/mm2
|
545 N/mm2
|
% Elongation
|
14.50
|
12
|
Bend test up to 22 mm
|
3D
|
4D
|
Bend test over 22 mm
|
4D
|
5D
|
Re bend test up to 10 mm
|
5D
|
5D
|
Re bend over 10 mm
|
7D
|
8D
|
Mass per unit length
Dia of bar
|
Weight
|
8
|
0.367-0.423
|
10
|
0.574-0.660
|
12
|
0.844-0932
|
16
|
1.499-1.660
|
20
|
2.393-2.544
|
25
|
3.734-3.965
|
28
|
4.685-4.975
|
32
|
6.121-6.499
|
Storing of reinforcement
• Different dia stored in different area.
• Separate supports so that they will not bend.
• Stored above ground level to avoid corrosion
• If stored for longer period they must be covered with some covering.
• Any rust material must be removed from steel before cutting and bending.
• Any material which is affecting the bond strength of steel must be removed from steel.
Structural steel sections
Hot rolled steel sections
• Angle sections
• Channel sections(ISJC, ISLC, ISMC)
• I sections(ISJB, ISLB, ISMB, ISHB)
• T sections
• Plane metal sheets, corrugated sheets, sheet piles, rail sections, flats of varying width, Cold formed light gauge steel sections.
Reinforcement corrosion
Reactions during corrosion
Effect of corrosion on RCC
• Cracking
• Delamination
• Spalling
• Loss of structural strength
Main causes of corrosion
Carbonation
• Caused because of CO2 gas. It will react with Ca(OH)2 to form calcium carbonate. This will reduce the alkalinity of concrete.
• Rate of carbonation depend upon following factors
1. Relative humidity
2. Grade of concrete,
3. Permeability of concrete,
4. Whether concrete is protected or not,
5. Depth of cover,
6. Time
• Measurement of extent of carbonation can be done by treating concrete with phenopthalein in diluted alcohol. If carbonation is not there colour will be pink and if it is carbonated concrete will remain uncolored
Chloride attack
• Caused because of reduction in alkalinity of concrete due to the attacks of chloride ions. They mainly enter into concrete from
1. Deliberate addition of admixtures
2. Use of salty water for mixing the concrete
3. Chloride contaminated aggregates
4. Attack of sea water
5. Attack of chemicals
Relationship between w/c, depth of cover and time in years for carbonation depth to reach the reinforcement
W/C ratio
|
Depth of cover in mm
| |||
15
|
20
|
25
|
30
| |
0.45
|
100
|
100
|
100
|
100
|
0.50
|
56
|
99
|
100
|
100
|
0.55
|
27
|
49
|
76
|
100
|
0.60
|
16
|
29
|
45
|
65
|
0.65
|
13
|
23
|
36
|
52
|
0.70
|
11
|
13
|
30
|
43
|
Limit of chloride content of concrete as per IS 456- 2000
Sr. No.
|
Type or Use of concrete
|
Maximum total acid soluble chloride content Expressed as Kg/m3 of concrete
|
1
|
Concrete containing metal and steam cured at elevated temperature and prestressed concrete
|
0.4
|
2
|
Reinforced concrete or plain concrete containing embedded metal.
|
0.6
|
3
|
Concrete not containing embedded metal or any material requiring protection from chloride
|
3.0
|
Corrosion control
Design and detailing
• Low permeability concret
• Nominal cover to the reinforcement
• Use of mineral admixtures
• Crack width control
Alternative reinforcement
• Fusion bonded epoxy coating
• Galvanized reinforcement
• Stainless steel reinforcement
Fusion bonded epoxy coating
• It is basically epoxy coating applied on to the reinforcement.
• Applied in plants and not on site.
• Coating thickness 130 to 300 micron.
• Looks greenish in colour
• First bars are sand blasted and then bars are heated up to controlled temperature and then coating is applied.
Limitations
• After coating if u do cutting and bending some time it may cause damage to the reinforcement coating.
• The coating is not possible on sites.
• Any defect in reinforcement coating may cause localized corrosion of the bars.
• Epoxy coating will not provide resistant to UV rays and hence bars should not be kept exposed in sun for longer time.
• The bars can not be welded.
• The coating may get damaged during the vibration of concrete.
• The epoxy coating is costly as costly as reinforcement.
Galvanized reinforcement
• Hot dip galvanized coating bars. Used only for aggressive exposure conditions, precast construction.
• It produced by dipping the steel bars in molten zinc.
• When zinc corrodes it will form Hydrated zinc oxide which will act as a insulator which will further prevent corrosion.
• Better bond strength
• Steel accessories which are used in RCC like fittings and inserts which are partially exposed should be galvanized.
• This coating will ensure design strength of steel, avoid spalling of concrete and corrosion of reinforcement.
• IS 12594-1988
Stainless steel reinforcement
• Stainless steel is highly corrosion resistant steel which contain almost 12 % of chromium. This chromium creates and invisible coating which will avoid corrosion of the reinforcement bars.
• It is available in four types
• Ferritic- Low carbon steel with less than 17% of chromium
• Ferritic austenitic- Low carbon steel with less than 22 to 28 % of chromium and 4 to 8 % of nickel.
• Austenitic-Low carbon steel with less than 17% of chromium and 8 % of nickel
• Martensitic.carbon content high as 1.2 % and chromium content of about 12 to 18 %
• Very good corrosion resistance property because of presence of chromium.
• Good strength and ductability and weldability.
• The main disadvantage is that they are quite costly as compared to normal reinforcements.
Coatings on concrete
• Polymer concrete overlays
• Latex modified concrete overlays
• Silica fume concrete
• Waterproof membrane or coating
Coatings
Polymer concrete coatings
• This is a coating of a material where Portland cement is replaced by polymers.
• It avoid the ingress of water and chloride ions and avoid the corrosion.
• It is expensive and difficult to prepare and hence mainly used as a repair material.
• Coating thickness is almost of about 12 mm.
•
Latex modified polymer coatings
• This is basically mixture of normal portland cement concrete of very low water cement ratio in which polymer latex emulsion are added in that.
• Water present in the emulsion hydrates the cement and polymer increase the bonding capacity of cement paste.
• This coating is generally applied in thickness ranging from 40 to 55 mm.
Silica fume concrete
• It is basically normal portland cement concrete in which silica fume is added.
• The silica fume is 10% by weight of cement.
• Plasticizers are required to mix in this concrete.
• This concrete is having low water content and hence very less permeability. Because of which it avoid the ingress of water and chloride ions in the concrete.
• The main disadvantage of this concrete is that there are lots of plastic shrinkage cracks in this concrete. Hence special precautions are required to avoid such plastic shrinkage cracks in this concrete.
•
Water proof membrane
• These are basically water proof coatings applied on to the concrete.
• These chemicals are made from combination of four additives like binder, inert filler, liquid solvents and admixtures.
• The performance of such coating mainly depend upon the type and selection of material, exposure conditions, working methods etc.
Corrosion inhibitors
• They are of three types
i. Anodic inhibitors- Chromates, nitrites, alkali phosphates, silicates and carbonates.
ii. Cathodic inhibitors- Zinc, magnesium, manganese and nickel
iii. Organic inhibitors- Amines, esters, Sulphonated blocks.
• Among all most widely used is calcium nitrite.
• It is added in the concrete as admixture.
• Dosage 10 to 30 litres per m3 of concrete
Chemical or Electro chemical method
• Cathodic protection
• Realkalisation
Cathodic protection
• Two types of anode are used. One is sacrificial anode or impressed current anode.
• Sacrificial anode systems consist of
iv. Strip or mesh type sacrificial anode made up of zinc, aluminium or magnesium alloy.
v. Ion conductive backfill (hydrogel and polymer system)
vi. Shielded electrical leads to be taken from anodes embedded steel reinforcement sacrificial anode.
• Mostly used in case of under ground structures and underwater structures.
• Chloride ions move away from steel reinforcement as they are drawn towards the externally placed anode.
Realkalisation
• Realkalisation is electrochemical process in which used to restore the alkalinity of concrete which will prevent corrosion of reinforcement.
• Realkalisation of concrete maintains the ph of concrete almost up to 12 initially.
• Realkalisation is performed by applying an electric current between the reinforcement and anode mesh placed temporarily in an electrolytic solution on the concrete surface.
• This electrolyte solution which is mainly sodium carbonate is transported into the carbonated concrete and maintain the alkalinity of concrete
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