Title: Specialty Concrete - High End Value Materials
1Specialty Concrete - High End Value Materials
2High-Value Concrete
- All concrete is high value!
- Cost of material (small)
- Cost of placement (significant)
- Cost of Replacement (HIGH)
3High-Value Concrete
- High value generally associated with
High-Performance - What is High-Performance?
- High-Early Strength Concrete
- High-Strength Concrete
- High-Durability Concrete
- Self-Consolidating Concrete
- Reactive Powder Concrete
4Characteristics of High-Performance Concretes
- High early strength
- High strength
- High modulus of elasticity
- High abrasion resistance
- High durability and long life in severe
environments - Low permeability and diffusion
- Resistance to chemical attack
5Characteristics of High-Performance Concretes
- High resistance to frost and deicer scaling
damage - Toughness and impact resistance
- Volume stability
- Ease of placement
- Compaction without segregation
- Inhibition of bacterial and mold growth
6Materials Used in High- Performance
Concrete
Material Primary Contribution/Desired Property
Portland cement Cementing material / Durability
Blended cement Cementing material / Durability / High strength
Fly ash / Slag / Silica fume Cementing material / Durability / High strength
Calcined clay/ Metakaolin Cementing material / Durability / High strength
Calcined shale Cementing material / Durability / High strength
Superplasticizers Flowability
High-range water reducers Reduce water-cement ratio
Hydration control admix. Control setting
7Materials Used in High- Performance
Concrete
Material Primary contribution/Desired property
Retarders Control setting
Accelerators Accelerate setting
Corrosion inhibitors Control steel corrosion
Water reducers Reduce cement and water content
Shrinkage reducers Reduce shrinkage
ASR inhibitors Control alkali-silica activity
Improve workability/reduce paste
Polymer/latex modifiers
Optimally graded aggr.
Durability
8Selected Properties of High- Performance
Concrete
Property Test Method Criteria that may be specified
High Strength ASTM C 39 70-140 MPa _at_ 28 to 91 days
H-E Comp. Strength ASTM C 39 20-30 MPa _at_ 3-12 hrs or 1-3 days
H-E Flex. Strength ASTM C 78 2-4 MPa _at_ 3-12 hrs or 1-3 days
Abrasion Resistance ASTM C 944 0-1 mm depth of wear
Low Permeability ASTM C 1202 500 to 2000 coulombs
Chloride Penetration AASHTO T 259/260 Less than 0.07 Cl at 6 months
Low Absorption
ASTM C 642
ASTM C 469
High Mod.of Elast.
More than 40 GPa
9High-Early-Strength Concrete
- High-early compressive strength
- ASTM C 39 (AASHTO T 22)
- 20 to 28 MPa (3000 to 4000 psi)
- at 3 to 12 hours or 1 to 3 days
- High-early flexural strength
- ASTM C 78 (AASHTO T 97)
- 2 to 4 MPa (300 to 600 psi)
- at 3 to 12 hours or 1 to 3 days
10High-Early-Strength Concrete
May be achieved by
- Type III or HE high-early-strength cement
- High cement content 400 to 600 kg/m3
(675 to 1000 lb/yd3) - Low water-cementing materials ratio (0.20 to 0.45
by mass) - Higher freshly mixed concrete temperature
- Higher curing temperature
11High-Early-Strength Concrete
May be achieved by
- Chemical admixtures
- Silica fume (or other SCM)
- Steam or autoclave curing
- Insulation to retain heat of hydration
- Special rapid hardening cements
12High-Strength Concrete
- 90 of ready-mix concrete
- 20 MPa - 40 MPa (3000 6000 psi) _at_ 28-d (most
30 MPa 35 MPa) - High-strength concrete by definition
- 28 day compr. strength
- ? 70 MPa (10,000 psi)
13High-Strength Concrete Materials
Aggregates
- 9.5 - 12.5 mm (3/8 - 1/2 in.) nominal maximum
size gives optimum strength - Combining single sizes for required grading
allows for closer control and reduced variability
in concrete - For 70 MPa and greater, the FM of the sand should
be 2.8 3.2. (lower may give lower strengths and
sticky mixes)
14High-Strength Concrete Materials
Supplementary Cementing Materials
- Fly ash, silica fume, or slag often mandatory
- Dosage rate 5 to 20 or higher by mass of
cementing material.
15High-Strength Concrete Materials
Admixtures
- Use of water reducers, retarders, HRWRs, or
superplasticizers mandatory in high-strength
concrete - Air-entraining admixtures not necessary or
desirable in protected high-strength concrete. - Air is mandatory, where durability in a
freeze-thaw environment is required (i.e..
bridges, piers, parking structures) - Recent studies
- w/cm 0.30air required
- w/cm lt 0.25no air needed
16High-Strength Concrete
Placing, Consolidation, and Curing
- Delays in delivery and placing must be
eliminated - Consolidation very important to achieve strength
- Slump generally 180 to 220 mm (7 to 9 in.)
- Little if any bleedingfog or evaporation
retarders have to be applied immediately after
strike off to minimize plastic shrinkage and
crusting - 7 days moist curing
17High-Durability Concrete
- 1970s and 1980s focus on High-Strength HPC
- Today focus on concretes with high durability in
severe environments resulting in structures with
long life High-Durability HPC
18High-Durability Concrete
Durability Issues That HPC Can Address
- Abrasion Resistance
- Blast Resistance
- Permeability
- Carbonation
- Freeze-Thaw Resistance
- Chemical Attack
- Alkali-Silica Reactivity
- Corrosion rates of rebar
19High-Durability Concrete
Confederation Bridge, Northumberland Strait,
Prince Edward Island/New Brunswick, 1997
- Cement 398 kg/m3 (671 lb/yd3)
- Fly ash 45 kg/m3 (76 lb/yd3)
- Silica fume 32 kg/m3 (72 lb/yd3)
- w/c 0.30
- Water Red. 1.7 L/m3 (47 oz/yd3)
- HRWR 15.7 L/m3 (83 oz/yd3)
- Air 5-8
- 91d strength 60 MPa (8700 psi)
20Self-Consolidating Concrete
Self-consolidating concrete (SCC) also known as
self-compacting concrete flows and consolidates
on its own
- developed in 1980s Japan
- Increased amount of
- Fine material (i.e. fly ash or limestone filler)
- HRWR/Superplasticizers
- Strength and durability same as conventional
concrete
21Self-Consolidating Concrete
22SCC for Power Plant in PennsylvaniaMix
Proportions
Portland cement (Type I) 297 kg/m3 (500
lb/yd3) Slag cement 128 kg/m3 (215
lb/yd3) Coarse aggregate 675 kg/m3 (1,137
lb/yd3) Fine aggregate 1,026 kg/m3 (1,729
lb/yd3) Water 170 kg/m3 (286
lb/yd3) Superplasticizer ASTM C 494, Type F
(Polycarboxylate-based) 1.3 L/m3 (35
oz/yd3) AE admixture as needed for 6 1.5 air
content
23Reactive-Powder Concrete (RPC)
- Properties
- High strength 200 MPa (can be produced to 810
MPa) - Very low porosity
- Properties are achieved by
- Max. particle size ? 300 ?m
- Optimized particle packing
- Low water content
- Steel fibers
- Heat-treatment
24Mechanical Properties of RPC
Property Unit 80 MPa RPC
Compressive strength MPa (psi) 80 (11,600) 200 (29,000)
Flexural strength MPa (psi) 7 (1000) 40 (5800)
Tensile strength MPa (psi) 8 (1160)
Modulus of Elasticity GPa (psi) 40 (5.8 x 106) 60 (8.7 x 106)
Fracture Toughness 103 J/m2 lt1 30
Freeze-thaw RDF 90 100
Carbonation mm 2 0
Abrasion 10-12 m2/s 275 1.2
25Reactive Powder Concrete
26Raw Material Components
- Cement
- Sand
- Silica quartz
- Silica fume
- Micro-Fibres - metallic or poly-vinyl acetate
- Mineral fillers - Nano-fibres
- Superplasticizer
- Water
27uctal
What is the typical Ductal mix ?
Cement
710 kg/m3
Silica fume
230 kg/m3
Crushed Quartz
210 kg/m3
Sand
1020 kg/m3
Fibres
Superplasticizer
40 - 160 kg/m3
13 kg/m3
Total water
140 kg/m3
No aggregates !
28uctal
What is the typical Ductal mix ?
Cement
28 - 30
Silica fume
9 10
Crushed Quartz
8.5 9
Sand
42 43
Fibres
Superplasticizer
1.7 6.5
Total water
0.6
5.5 6
No aggregates !
w/c 0.20