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you would be aware about the different types of special concrete being used in india.All these types of concrete are being produced by ultratech concrete, for more details visit www.ultratechconcrete.com/concrete_types.html
you would be aware about the different types of special concrete being used in india.All these types of concrete are being produced by ultratech concrete, for more details visit www.ultratechconcrete.com/concrete_types.html
Highway Construction Materials and PracticeSenthamizhan M
Sub grade soil is an integral part of the road pavement structure as it provides the support to the pavement from beneath.
The sub grade soil and its properties are important in the design of pavement structure.
The main function of the sub grade is to give adequate support to the pavement and for this the sub grade should possess sufficient stability under adverse climatic and loading conditions.
Introduction of concrete
Historic development
Composition of concrete
Advantages of concrete over other materials
Advances and future trends in concrete
Overview of Sustainability and Concrete development.
Introduction to Concrete
Manufacturing of Concrete
Types of Concrete
Properties of Concrete
Advantage of Concrete
Uses of Concrete
Various Tests for Concrete
Innovations…
Cellular Lightweight Concrete is also known as CLC. In other words, CLC is also known as foamed concrete. The CLC is widely used for construction purposes as it has various advantages and usage than the traditional concrete bricks.
The foamed concrete is manufactured from mixing of Portland cement, sand, fly ash, water and performed foam in varied proportions. This CLC (Cellular Lightweight Concrete) can be produced at building sites with the use of machines and molds used for normal concrete.
One of an important characteristic of foamed concrete is it has self-compacting property as there is no compaction is required. And also, it easily flows out from the pump to fill the mold. With this property is can be pumped to maximum distance and height.
For continuous cellular lightweight concrete is manufactured by mixing light mortar and preformed foam under pressure in a special static mixer.
The owner is required by law to:
o post the fire safety plan on the inside of every apartment front door.
o post the fire safety plan in a conspicuous space in the common area.
o distribute a copy to each dwelling unit in the building.
o provide a copy to new tenants at the time of the lease.
o re-distribute the fire safety plan annually during fire prevention week
The figure shows the section of a gravity dam built with concrete. Examine the stability of this section at the base. The earthquake forces may be taken as equivalent to 0.1g for horizontal forces and 0.05g for vertical forces. The uplift may be taken as equal to the hydrostatic pressure at the either ends and is considered to act over 60% of the area of the section. 1 in 10 6m A tail water depth of 6m is assumed to be present when the reservoir is full and there is no tail water when the reservoir is empty. Also indicate the values of various kinds of stresses that are developed at heel and toe. Assume weight of concrete = 24 kN/m³; and weight of water = 10 kN/m³
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Sub grade soil is an integral part of the road pavement structure as it provides the support to the pavement from beneath.
The sub grade soil and its properties are important in the design of pavement structure.
The main function of the sub grade is to give adequate support to the pavement and for this the sub grade should possess sufficient stability under adverse climatic and loading conditions.
Introduction of concrete
Historic development
Composition of concrete
Advantages of concrete over other materials
Advances and future trends in concrete
Overview of Sustainability and Concrete development.
Introduction to Concrete
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Properties of Concrete
Advantage of Concrete
Uses of Concrete
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Cellular Lightweight Concrete is also known as CLC. In other words, CLC is also known as foamed concrete. The CLC is widely used for construction purposes as it has various advantages and usage than the traditional concrete bricks.
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The owner is required by law to:
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o post the fire safety plan in a conspicuous space in the common area.
o distribute a copy to each dwelling unit in the building.
o provide a copy to new tenants at the time of the lease.
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The figure shows the section of a gravity dam built with concrete. Examine the stability of this section at the base. The earthquake forces may be taken as equivalent to 0.1g for horizontal forces and 0.05g for vertical forces. The uplift may be taken as equal to the hydrostatic pressure at the either ends and is considered to act over 60% of the area of the section. 1 in 10 6m A tail water depth of 6m is assumed to be present when the reservoir is full and there is no tail water when the reservoir is empty. Also indicate the values of various kinds of stresses that are developed at heel and toe. Assume weight of concrete = 24 kN/m³; and weight of water = 10 kN/m³
tend to form in some materials
•
Since
the fine materials are usually sensitive to moisture
the field Engineer must be extremely weather
conscious
•
If
heavy rain is expected the surface of the fine material
should be rolled smooth with sufficient gradient to shed
water from the working area
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11. A concrete dam can be assumed to be trapezoidal in section having a top width of 2 m and bottom width of 10 m. Its height is 12 m and the upstream face has a batter of 1: 10. Give an analysis of the stability of the dam for the base section for overturning and sliding in the full reservoir condition assuming no free-board allowance but allowing for uplift pressures. Assume uplift intensity factor ast 100%. Also determine the compressive stresses at the toe and the heel, and major principal and shear stress developed at the toe. Assume weight of concrete to be 24 kN/m³, unit shear strength of concrete
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R.L. of bottom of the dam
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Full reservoir level
= 312 m
Top width of the dam
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12. The following data refer to the non-overflow section of a gravity dam:
R.L. of top of the dam
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R.L. of bottom of the dam
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Full reservoir level
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Top width of the dam
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2. • Lecture Organization
1. An Introduction to Stabilization
• Definition and Objectives of Stabilization
• Methods of Stabilization:
• Chemical Stabilization: Lime, Cement and
Bitumen
• Mechanical Stabilization
• Factors Affecting Selection of Methods of Stabilization
2. Lime Stabilization
3. Cement Stabilization
4. Bitumen Stabilization
5. Mechanical Stabilization
2
CHAPTER 2.3: STABILIZED PAVEMENT
MATERIALS
3. 3
• Objective: After completing this lesson the
student is expected to understand:
1. The definition and objectives of stabilization.
2. The different methods of stabilization and factors
considered in selection of methods of stabilization.
3. Mixing and construction procedures and methods
of application of lime, cement and bitumen
stabilizations.
4. The techniques of stabilization by mechanically
blending of materials (Mechanical Stabilization).
CHAPTER 2.3: STABILIZED PAVEMENT
MATERIALS
4. CHAPTER 2.3: STABILIZED PAVEMENT
MATERIALS
I. An Introduction to Stabilization
• Pavement Design is based on the premise that specified
levels of quality will be achieved for each soil layer in the
pavement system.
• So that each layer must:
• resist shearing within the layer,
• avoid excessive elastic deflections, and
• prevent excessive permanent deformation through
densification.
• Hence, the quality of the material in each layer should meet
the specification requirement.
4
5. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
• However, in many instances fulfilling the specification
requirement is challenging due to:
1. The absence of quality material in the project vicinity.
2. The higher cost of transporting quality materials.
• Hence, improving the property of the available material will
become mandatory or economical.
• Stabilization is the process of altering/ improving the
properties of sub-grade and pavement materials either by
blending and improving particle gradation (Mechanical
Stabilization) or by using stabilizing additives to meet the
specified engineering properties (Chemical Stabilization).
5
6. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Objective of Stabilization:
• To improve the strength of weak pavement materials.
e.g. subgrade, subbase, base and low cost road
surface.
• To improve volume stability, shrinkage and swelling
of highly plastic materials under moisture.
• To improve durability: increase resistance to erosion,
weathering or traffic.
• To improve high permeability, poor workability, etc.
of the existing pavement materials.
6
7. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Methods of Stabilization
Stabilization is achieved by two methods:
1. Mechanical Stabilization is stabilization where the
stability of the soil is improved by blending the available
soil with imported soil or aggregate to obtain the desirable
particle size distribution.
• It is achieved by blending and grading with imported
materials.
2. Chemical Stabilization is stabilization where stabilizing
agents/ chemicals are used for bringing desired properties of
the pavement materials.
• It is achieved by using stabilizing agents: Bitumen and
Hydraulic Binders (e.g. Lime, Lime-Pozzolana, Cement,
etc.).
7
8. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Factors Considered in Selection of Stabilization
• Even though we have different methods of stabilizations, a
proper selection among the alternatives should be made
based on the following factors:
Factors affecting the selection of Stabilizing Agent:
1. Physical properties of the materials to be stabilized (PI &
Gradation).
2. Availability of the stabilizing agent.
3. Economic feasibility of the different methods.
4. Ease of work procedure and workmanship or construction
method.
5. Site condition, safety, curing time, etc. 8
9. Hence, according to ERA Pavement Design Manual, the
selection of stabilizer based on the PI and gradation
requirement:
Type of
Stabilizer
Soil/ Material’s Property
>25% Passing the 0.075mm Sieve <25% Passing the 0.075mm Sieve
PI<10 10<PI<20 PI>20 PI<6 and
PP<60
PI<10 PI>10
Cement Yes Yes * Yes Yes Yes
Lime * Yes Yes NO * Yes
Lime-Pozzolana Yes * NO Yes Yes *
Note:1. * Indicate that the stabilizer will have marginal effectiveness
2. PP (Plasticity Product) = PI X % passing 0.075mm sieve 9
Chapter 3: Stabilized Pavement
Materials
11. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
According to the above table and diagram:
1. If the soil has high plasticity, this indicate that it contains
more clay minerals which can readily react with lime,
hence lime is the best stabilizing agent.
2. Cement is more difficult to react with high plastic
materials but good stabilizing agent for low plastic
materials.
3. Reactive silica in the form of pozzolana (Lime-Pozzolana)
can be added to the soil with low plasticity to make them
suitable for lime stabilization.
4. Bitumen is more suitable for granular materials with low
PI. 11
12. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
II. Lime Stabilization
Lime is a cementing material found in different forms:
1. Hydrated (Slaked) lime [Calcium Hydroxide
Ca(OH)2]
2. Quicklime [Calcium Oxide (CaO)]
3. Dolomite lime (Calcium-Magnesium Carbonate)
4. Agricultural lime (Calcium Carbonate)
Agricultural lime is not suitable for stabilization, and
dolomite lime is not usually as effective as hydrated lime
or quicklime.
12
13. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Hence, the commercially available lime for
Stabilizations are:
a. Hydrated lime in dry very fine powder
form
b. Hydrated lime in slurry form
c. Quick lime
13
14. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
The following table summarizes the properties of the above
mentioned lime forms:
14
Hydrated Lime Quick Lime Slurry Lime
Composition Ca(OH)2 CaO* Ca(OH)2
Forms Very fine powder Granular Slurry
Equivalent Ca(OH)2 /
Unit Mass 1 1.32 0.56 to 0.33**
Bulk Density
(tone/m3) 0.224 -0.271 0.507 0.608
NB:
*CaO + H2O Ca(OH)2 + Heat
** Moisture Content of slurry may vary from 80% to over 200%
18. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Mechanism of Stabilization by Lime [Chemical Reaction]
18
Un-stabilized Clay Particles
Untreated clays have a
molecular structure similar to some
polymers, and give plastic
properties. The structure can trap
water between its molecular layers,
causing volume and density
changes.
Clay after treatment with
lime
In treated clays, Calcium atoms
(from Lime) have replaced Sodium
and Hydrogen atoms producing a
soil with very friable characteristics.
On-going reaction with available
Silica and Alumina in the soil forms
complex cementitious materials (the
pozzolanic effect).
20. 22
EFFECT OF LIME ON ENGINEERING PROPERTIES OF SOILS
Immediate Impact on Plasticity, Workability,
and Load Bearing Capacity
After Treatment
Before Treatment
Liquid Range
Plastic Range
Solid Range
PI
(PI)’
Increasing Water Content
PL Wn LL
(LL)’
W’n (PL)’
Drying: The water content is reduced from Wn to
W’n
Plasticity: Treatment with lime displaces the solid
range to the right. This enables the soil to accept a
higher water content while remaining solid. The
plasticity index PI=LL-PL
is reduced.
70
60
40
30
20
15
10
9
8
4
3
2
0
CBR
%
W %
0 12 14 16 18 20
UNTREATED
0.5 % LIME
3% LIME
Increase in carrying capacity
after liming: After 2 hours with an
initial water content of 14% the CBR
index increased from 9 to 30 (0.5%
lime added) and 70 (3% lime added)
respectively.
22. III. Cement Stabilization
• Cement Treated Base: an intimate mixture of native
and/or manufactured aggregates with measured amounts of
cement and water that hardens after compaction and curing
form a strong and durable paving material.
• There are two types cement stabilized materials in highway
construction:
1. Soil Cement: it contains enough cement (usually >
3%) to pass standard durability tests and achieves
significant strength increase.
24
CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
23. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
2. Cement Modified Soil an unhardened or semi-
hardened mixture of soil, water, and small quantities
of cement.
• There are different types of cement in use.
• However, regardless of the type, cement acts both as a
cementing agent and a modifier.
25
24. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
• In primarily coarse graded soils, the cement paste bonds
the soil particles together by surface adhesion forces
between the cement gel and the particle surfaces.
• In fine-grained soils, the clay phase may also contribute
to the stabilization process through reaction of the free
lime from the cement.
• In the second case, cement acts as a modifier by reducing
the plasticity and expansion properties of the soil.
26
25. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Soils Suitable for Cement Stabilization
• As discussed before a wide range of soil types may be
stabilized using cement. However, it is generally more
effective and economical to use it with:
1. Granular soils due to:
• the ease of pulverization and mixing
• the smaller quantities of cement required
2. Fine grained soils of low to medium plasticity can
also be stabilized, but not as effectively as coarse-
grained soils.
27
26. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Cement Stabilisation:
General guidelines on cement requirement to stabilise soil:
28
Amount of cement (%)
Soil type By weight By volume
A-1-a 3-5 5-7
A-1-b 5-8 7-9
A-2 5-9 7-10
A-3 7-11 8-12
A-4 7-12 8-13
A-5 8-13 8-13
A-6 9-15 10-14
A-7 10-16 10-14
30. • Mixture design step for Lime/ Cement Stabilized Materials:
1. Determine moisture-density relationship:
• Select expected median cement content (e.g. 6% by estimated
dry weight),
• Perform standard or modified Proctor test,
• Construct moisture-density curve,
• Determine optimum moisture content and maximum dry
density.
32
31. 2. Mold specimens for compressive strength testing:
• Select range of cement contents (e.g. 4%, 6% and 8% by
dry weight of material).
• Use OMC (Optimum Moisture Content) from Step 1 and
mold two specimens per cement content.
• Perform compressive strength testing.
• Plot Cement content versus compressive strength.
33
33. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
3. Determine moisture-density relationship of target cement
content.
• Perform standard or modified Proctor test.
• Construct moisture-density curve.
• Determine optimum moisture content and maximum
dry density.
35
34. • There are two construction
methods:
1. Plant Mix
2. Road Mix (in-place)
1. Plant Mix: Pug mill
• High production.
• High mobilization &
demobilization cost.
36
Chapter 3: Stabilized Pavement
Materials
35. 2. Road Mix
• In-situ or mixed in place materials.
• Dry or slurry cement application method.
37
36. • Road mix procedures:
1. Spread the cement in predefined or calculated
amount.
2. Add water if necessary based on the method of
mixing we use and then mix the cement-soil blend.
3. Grade and compact using suitable rolling equipment.
4. Cure the mixture.
38
39. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
IV. Asphalt Stabilization
• Asphalt stabilization of pavement material is usually
intended either to:
• introduce some cohesion into non-plastic materials,
• make a cohesive material less sensitive to loss of
stability with increased moisture.
• The process is more successful with granular material
than with cohesive material.
• Asphalt stabilization is therefore primarily used on base
and, to a lesser extent, sub base materials.
• Typical binder contents range from 4% to 8%. 41
40. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Bituminous stabilization may be carried out with any of
the following materials:
• Hot Asphalt Cement,
• Cutback Asphalt,
• Asphalt Emulsion, either as Cationic or Anionic
Emulsion
Stabilization with Hot Asphalt Cement
• Foamed Asphalt Process
42
41. Stabilization can be carried out in place or in a central
plant.
Foamed asphalt allow only a very short mixing time
while the asphalt is in a finely dispersed condition.
The fine aggregate particles are substantially coated with
asphalt, leaving the coarse particles relatively uncoated
with asphalt.
Materials with maximum plasticity index of 6–15 can be
stabilized using this type of treatment.
43
Chapter 3: Stabilized Pavement
Materials
42. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Stabilization with Cutbacks
• The cutback asphalt can be sprayed cold or with slight
heating and mixed with pre-moistened soil.
• This method of stabilization results in a material that
gains strength very slowly and as a result, it is not used
very frequently.
• Environmental constraints often limit the use of
cutbacks in urban areas.
44
43. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Stabilization with Asphalt Emulsion
• Asphalt emulsions may be readily mixed with damp soil
to produce a good dispersion of asphalt throughout the
soil.
• Asphalt emulsions are most widely used for soil
stabilization.
• Asphalt emulsions are produced at three different
grades: Slow Setting(SS), Medium Setting(MS), &
Rapid Setting(RS) asphalt emulsions.
45
44. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
Construction Factors Affecting Design
Considerations:
If you should stabilize with emulsion or cutback asphalts
the following points guides the selection.
• In hot and dry areas, medium to slow setting cutback/
emulsion asphalts can be used, depending on the soil
type,
• In cooler areas, medium to rapid-setting cutbacks/
emulsion would be used.
However, foamed asphalt stabilization is not subject to
climatic restrictions for mixing and compaction. 46
45. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
To achieve good results with asphalt stabilized materials in
the field, you must:
• thoroughly mix the stabilizing agent throughout the soil,
• ensure that the soil is compacted at a uniform moisture
condition, and
• ensure adequate aeration of emulsion and cutback
stabilized materials to allow the excess moisture and/or
volatiles to escape.
47
46. The ERA Pavement Design Manual identifies three types of
stabilized materials used in the design catalog. These are
• Cement or Lime Stabilized Road Base 1 (CB1)
• Cement or Lime Stabilized Road Base 2 (CB2)
• Cement or Lime Stabilized Sub Base (CS)
48
Chapter 3: Stabilized Pavement
Materials
47. The strength requirements of the cement/ lime stabilized
materials is given in ERA Pavement Design manual as:
Code Description Unconfined compressive
Strength (UCS) Mpa
(for Cement stabilized)
Minimum CBR (%) (for
lime Stabilized)
CB1 Stabilized base 3.0- 6.0 100
CB2 Stabilized base 1.5 -3.0 80
CS Stabilized sub
base
0.75 – 1.5 40
N:B: Strength test is conducted on 150mm cube.
49
Chapter 3: Stabilized Pavement
Materials
48. CHAPTER 3: STABILIZED PAVEMENT
MATERIALS
V. Mechanical Stabilization
• Is an improvement of an available material by blending it with
imported materials to improve the gradation and plasticity
characteristics of the material.
• Materials produced by blending (mechanically stabilized) are
still unbound granular materials their characterizations and
testing are similar to the conventional granular materials.
• The mix design of mechanically stabilized material is based on:
1. Gradation requirement
2. Plasticity property requirements
3. Strength test requirements (CBR) 50
49. 51
Sieve Designation
Grading
A B C D E F
Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. Max.
2 in. (50mm) 100 100 - - - -
1 in. (25mm) - 75 95 100 100 100 100
3/8 in. (9.5mm) 30 65 40 75 50 85 60 100 - -
No. 4 (4.75mm) 25 55 30 60 35 65 50 85 55 100 70 100
No. 10 (2.00mm) 15 40 20 45 25 50 40 70 40 100 55 100
No. 40 (0.475mm) 8 20 15 30 15 30 25 45 20 50 30 70
No. 200 (0.075mm) 2 8 5 20 5 15 5 20 6 20 8 25
AASHTO Gradation limit for Soil –Aggregate sub base, base and surface
course
50. 52
(Proportion of Material “A” x % Pass of
Material “A” + Proportion of Material “B” x
% pass of Material “B”+ …….)
% Pass of Blend =
Proportion of “A” + Proportion of “B” + ……..
PI of Blend =
{(% A) (% Passing No.40, A)(PI,A) + (% B) (% Passing No.40, B)(PI,B)
(% A) (% Passing No.40, A) + (% B) (% Passing No.40, B)
51. It is desired to combine two materials A which is the soil at the existing
road bed and B which is obtained from the near by borrow pit. If the
required gradation is AASHTO Grading "C". Determine the Blending
Proportion and the resulting PI of the blended soil .
53
Property
Specification
Requirement
Sub grade
Soil (A)
Borrow
Material (B)
Mechanical Analysis Min Max
2 in. (50mm) -
1 in. (25mm) 100 100 100
3/8 in. (9.5mm) 50 85 68 45
No. 4 (4.75mm) 35 65 46 28
No. 10 (2.00mm) 25 50 36 17
No. 40 (0.475mm) 15 30 32 7
No. 200 (0.075mm) 5 15 17 3
Plasticity Characterstics
Liqudity Limit (%) 40 13
Plasticity Index (%) 12 3
QUIZ -1: (10 %)