IJSTE - International Journal of Science Technology & Engineering | Volume 2 | Issue 05 | November 2015
ISSN (online): 2349-784X
Model for Repair Urgency in RC Structure using
NDT Data
Harsh Mahajan
Assistant Professor
Department of Civil Engineering
Shri Vaishnav Institute of Technology & Science Indore [M.P.]
Sudhir S Bhadauria
Professor
Department of Civil Engineering
Rajiv Gandhi Proudyogiki Vishvavidyalaya, Bhopal [M.P.]
Shakti Sagar Pandey
Junior Research Fellow
Shri Govindram Seksaria Institute of Technology and Science Indore [M.P.]
Abstract
Monitoring of concrete structure like buildings, bridges etc is very essential to ensure safety, stability and serviceability. The
structure should, not only being safe, also be functioning as its intended use. Heavy cracking, excessive deflections, corrosion,
spalling of concrete, surface stains are main characteristics of the degraded properties of a RC structure. The final goal of
condition assessment of a building is to find the urgency of repair, nature of repair and cost associated with repairing. A
condition assessment model based on five parameter: Visual inspection, ultrasonic pulse velocity, resistivity of concrete and age
factor was prepared. On the basis of above condition index, repair urgency associated with structure was assigned. Prepared
model then applied to existing structures.
Keywords: Condition assessment, Degradation of concrete, Non-destructive tests, Repair urgency, Structural health
monitoring
________________________________________________________________________________________________________
I. INTRODUCTION
The reinforced cement concrete has been the first choice to be used as building material, because of its high strength, economy
and durability. Reinforced concrete structures have the potential to be durable and capable of withstanding a variety of adverse
environmental conditions however premature failure of structure often observed as a result of corrosion of reinforcement due to
chloride ingress and carbonation, sulphate attack, cracks due to temperature/moisture fluctuations etc. Assessment of structural
characteristics viz. residual Strength of concrete, corrosion etc are used to identify current situation and future durability problem
of structure, which is the basic need of maintenance plan. Current durability status of structure helps in prediction of its residual
life. This assessment also helps in determining the life cost of structure which includes construction cost, maintenance cost,
operational cost etc. By condition assessment, one can decide the repair urgency of RC structure.
II. RELATED WORK
Sasmal et al. [1] explored the possibilities of using fuzzy mathematics for condition assessment and rating of bridges. Author had
developed a systematic procedure and formulations for rating existing bridges using fuzzy mathematics. Grigg [2] reports
advances in condition assessment for water distribution pipes which can be also applied to transmission, in plant and service pipe
line. Author had presented a definition and framework for condition assessment, plan for renewal of pipe and also utility
practices in implanting the available method and technology. Bhadauria and Gupta [3] presented a systematic in-situ condition
assessment, documentation, survey of water tank structures, which had been done on an empirical damage scale of 0 to 10.
Caner et al.[4] had proposed a simple method to assess the remaining service life of a bridge by defining a relationship between its
current condition rating and its age by evaluating a set of bridges at different ages. Semaan et al. [5] developed a condition
assessment model (subway station diagnosis index). It also utilized both the Preference Ranking Organization method of
Enrichment Evaluation and the Multi-attribute Utility Theory to determine the station diagnosis index SDI. Mitra et al. [6]
presented a method for obtaining condition index of corrosion distressed RC buildings. Method had been developed using
concepts of fuzzy logic and it integrates visual inspection with in situ investigations. Yokota et al. [7] proposed a simplified
assessment system of RC member suffered from chloride-induced corrosion as the deterioration grading system (a,b,c,d). To link
it to structural performance a total of 30 reinforced concrete slabs extracted from superstructures of open-type wharves aged 30
to 44 years was experimentally load tested to examine the load-carrying capacities after corrosion of reinforcement occurred.
Few decades ago the repair prioritization of a RC building was done by combination of visual inspection, knowledge and
experience. There is always a need of research to quantify current condition. In above paper few paper are based on fuzzy logic
analysis of visual inspection data but only visual inspection data cannot be a parameter for decision making.
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70
Model for Repair Urgency in RC Structure using NDT Data
(IJSTE/ Volume 2 / Issue 05 / 012)
III. PROBLEM FORMULATION
As explicit relation between the variety of condition assessment data and the corresponding repair urgency cannot be achieved
and also implicit functions are also difficult to develop. Hence a rational formulation for comparison of urgency of repair can be
a useful and a consistent tool. A number of factor will be introduce viz. visual inspection, rebound hammer, ultra sonic pulse
velocity, resistivity meter and age factor. All arrange in a condition indexing say 0-5 every parameter will be measured as
Condition Index.
Table - 1
Proposed condition rating and associated repair priority
Condition Index
Definition based on repair priority scale
0
No requirement of repair
1
Very low priority, repair can be delayed for long time, not urgent
2
Low priority repair, Repair can be delayed for significant time
3
Medium priority repair, Repair action might be required
4
High priority repair, Repair action required urgently
5
Very high priority repair, Condition is critical
IV. MODEL FOR REPAIR URGENCY
Parameters used in condition assessment: Visual inspection, Concrete Strength, Concrete Quality, Concrete resistivity, Actual
Life / Estimated service life.
A. Visual Inspection
Rational categorization for visual inspection is done by combining two inputs Rusting/cracks, Delamination/spalling are used on
basis of manifestation presented in Mitra et al. [6]:
Table - 2
State of Distress condition
State
Distress condition
Manifestation: ‘Rusting/Cracks’
1
No visible crack on the surface
2
Rusting with some cracks parallel to rebar in one direction
3
Rusting with several cracks parallel to rebar in both directions
4
Rusting with extensive cracks parallel to rebar in both directions
Manifestation: ‘Delamination/spalling’
1
No visible delamination or spalling on the surface
2
Some delamination with no spalling
3
Extensive delamination with considerable spalling
4
Extensive delamination, extensive spalling
5
Extensive delamination, extensive spalling with some broken stirrups and buckled main
Combination of the above visual inspection data gives 1 to 5 Condition Indexing.
Delamination/spal
ling
Table - 3
Condition State according to Distress Manifestation
Manifestation Rusting/Cracks
State
1 2 3 4
1
1 1 2 3
2
1 2 3 4
3
2 3 4 4
4
3 4 4 5
5
4 4 5 5
B. Concrete Strength
In situ concrete strength is generally measure by using correlation between rebound number and compressive strength British
standard institution [8].
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71
Model for Repair Urgency in RC Structure using NDT Data
(IJSTE/ Volume 2 / Issue 05 / 012)
In condition assessment practices, the estimated in situ concrete strength values are checked against acceptance criteria
(British standard 2007) is adopted.
fi i ≥ .8 f k −
........1
Repair action will not be required if the estimated concrete strength value satisfies acceptance criteria by considering Factor of
Safety. FOS=1.2(BS 1981).
fi
≥
i
.8 X .
f
k
−
........2
C. Concrete Quality
Concrete quality is generally assessed by measuring ultra-sonic pulse velocity by penetrate it through concrete. International
atomic energy agency (IAEA [9] ) recommends concrete quality corresponding to different pulse velocity.
D. Deterioration Specific Parameters
Resistivity of concrete: According to CPWD Handbook
taken
[10]
and IAEA [9], resistivity of concrete and corrosion susceptibility was
E. Current Age/ Estimated Service Life
Only carbonation is considered as degradation parameter, following equations may be used to calculate estimated service life.
From Sarja & Vesikari [11] Initiation period due to carbonation
�
� =
......3
��
to = Time of initiation in years; c= Concrete cover (mm) Kc = Carbonation Depth depends on various factors
According to Hakkinen[14]:
......4
K = ce c i a f k + 8
cenv = environmental coefficient= 1 and 0.5 for structures sheltered from rain and structures exposed to rain respectively; c air =
air content coefficient= 1 and 0.7 in non air- entrained and air-entrained concrete, respectively; a and b = 1,800 and −1.7 for
Portland cement = 360 and −1.2 for Portland cement +28% fly ash
Propagation time based on cracking of concrete cover:
t =8
.... .5
D
where, c = Concrete Cover in mm ; D = Diameter of Bar in mm; r= rate of corrosion of steel in concrete µm/year; According
to Firodiya et al. (2015): Average Corrosion rate
Table - 8
Average Corrosion rate (Firodiya et al)
Exposure
condition
Reinforcement Bar
Mild Steel
Cold Deformed bar
Wet
5.2 µm/year
7.7 µm/year
Dry
5.7 µm/year
11.1 µm/year
Service Life = t + t
By estimating approximate service life of RC building, following condition indexing can be assigned to each member.
For combining all condition index of various parameters mean of all has been take
x̅ =
∑n
1
∑n
1
i i
i
.. ...6
Table - 9
Condition index and upper-lower limit of various parameters
Visual Inspection
Concrete Strength
LB
UB
LB
0
--
1
--
1
1
2
--
2
2
3
--
3
3
4
4
4
5
5
5
--
��
��
�
�
≥ .
--
Concrete Quality
UB
��
�
≥ .8 ��� −
��
�
Age Factor
LB
UB
LB
UB
LB
UB
--
3.50
--
20000
--
0.25
3.50
3.25
20000
15000
0.25
0.35
3.25
3.00
15000
10000
0.35
0.45
3.00
2.50
10000
5000
0.45
0.55
--
2.50
2.00
5000
2500
0.55
0.65
--
2.00
--
2500
--
0.65
--
≥ .
--
��� −
-��� −
Concrete Resistivity
≥ .8 ��� −
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72
Model for Repair Urgency in RC Structure using NDT Data
(IJSTE/ Volume 2 / Issue 05 / 012)
V. OBSERVATION AND RESULTS
Above model was applied on existing building, constructed 60 years ago. The USPV is measured by ultrasonic pulse velocity
meter, resistivity by concrete resistivity meter, Concrete strength by rebound hammer, age factor by applying specified model of
carbonation. On the basis of result Condition index and its normalised values are calculated and same produced in following
table. (R= reading)
Element ID
Table - 10
Observation of survey lab SGSITS Indore
Visual Inspection
USPV
Resistivity
Concrete Strength
R
CI
R
CI
R
Age factor
CI
R
CI
R
CI
Mean
Column
C1
4
4
0.99
5
10053.3
2
16.5
0
0.74
4
3.00
C2
3
3
1.65
5
12886.7
2
15.0
0
0.72
4
2.80
C3
5
5
2.09
4
14123.3
4
10.0
3
0.72
4
4.00
C4
4
4
1.69
5
11963.3
2
7.80
5
0.74
4
4.00
C5
3
3
1.49
5
8936.7
3
11.0
3
0.69
4
3.60
C6
2
2
1.47
5
11476.7
2
5.10
5
0.70
4
3.60
C7
2
2
1.01
5
20293.3
0
7.80
5
0.71
4
3.20
C8
4
4
0.90
5
12836.7
2
7.80
5
0.79
4
4.00
C9
5
5
1.27
5
14163.3
2
12.5
0
0.77
4
3.20
C10
3
3
1.41
5
19650.0
1
10.0
3
0.80
4
3.20
C11
4
4
1.66
5
19343.3
1
13.2
0
0.73
4
2.80
C12
5
5
1.86
5
23533.3
0
16.5
0
0.69
4
2.80
B1
4
4
2.48
4
15370.0
1
12.5
0
0.65
4
2.60
B2
4
4
2.33
4
16573.3
1
13.2
0
0.67
4
2.60
A1
4
4
2.18
4
36300.0
0
6.80
5
1.11
5
3.60
A2
4
4
1.49
5
20300.0
0
8.80
5
0.95
5
3.80
A3
5
5
1.70
5
16133.3
1
11.1
3
1.33
5
3.80
B1
3
3
2.35
4
23676.7
0
10.0
3
1.09
5
3.00
B2
3
3
2.38
4
17633.3
1
8.80
5
1.20
5
3.60
Beam
Slab
B3
2
2
1.69
5
17400.0
1
13.2
0
1.02
5
2.60
C1
2
2
2.93
3
32900.0
1
11.1
3
1.20
5
2.80
C2
4
4
1.84
5
20166.7
0
12.5
0
1.14
5
2.80
C3
5
5
1.91
5
20200.0
0
13.2
0
0.95
5
3.00
D1
3
3
1.55
5
35100.0
0
7.80
5
0.87
5
3.60
D2
4
4
2.56
3
17800.0
1
7.80
5
1.04
5
3.60
D3
3
3
1.95
5
17000.0
1
11.1
3
0.82
4
3.20
E2
5
5
2.33
4
36300.0
0
7.80
5
1.17
5
3.80
E3
4
4
2.73
3
15233.3
1
11.1
3
1.11
5
3.20
In slab total 14 points were chosen for test and on each point three readings were taken. In above table readings are the
average reading of observations taken. So, from above values and study, condition index of Survey lab = 3.28, hence its repair
urgency lies in high priority repair.
VI. CONCLUSION
A condition assessment model based on five parameter: Visual inspection, ultrasonic pulse velocity, resistivity of concrete and
age factor. Condition index for each parameter had been developed on basis of standard given in various research and
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73
Model for Repair Urgency in RC Structure using NDT Data
(IJSTE/ Volume 2 / Issue 05 / 012)
departmental guidelines. The produced model is applied on existing building and its repair priority was found to be High
Priority.
REFERENCES
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[3] Bhadauria S and Gupta M (2006), “In- Service Durability Performance of Water Tanks”, Journal of Performance of Constructed Facilities © ASCE 20.(2) /
May2006
[4] Caner A, Yanmaz A., Yakut A, Avsar O and Yilmaz T (2008). “Service Life Assessment of Existing Highway Bridges with No Planner Regular
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[5] Semaan N and Zayed T(2009) “Subway Station Diagnosis Index Condition Assessment Model”, Journal of Infrastructure System © ASCE 15(3)/
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[6] Mitra G, Jain K and Bhatacharjee B (2010) “Condition Assessment Of Corrosion Distressed Reinforced Concrete Buildings Using Fuzzy Logic” Journal of
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[8] British Standards Institution (2007). ”Assessment of in-situ compressive strength in structures and precast concrete components”, BS EN 13791, London
[9] International Atomic Energy Agency (IAEA) (2002) “Guidebook on non-destructive testing of concrete structures”, Training course series no.17, IAEATCS-17, Vienna, Austria
[10] Central Public Work Department (CPWD)(2002) “Handbook on repair and rehabilitation of RCC buildings, Government of India , New Delhi, India
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