FORENSIC ENGINEERING TESTING TECHNIQUES FOR STRUCTURAL ASSESMENT: A CASE STUDY ON PRE-STRESSED
REINFORCED CONCRETE BRIDGE AT KLANG VALLEY
GOPINATH MUNIANDY
A project report submitted in partial fulfillment of requirement for the award of the degree of
Master of Science (Construction Management)
Faculty of Civil Engineering
UnNersiti Teknologi Malaysia
ABSTRACT
Integrity test on existing concrete structures is often being carried out to determine the assessment for the structure through several aspects such as to determine the whether the structure is suitable for its designed use, for proposed change of usage or extension of a structure, to enswe the acceptability of structure following to any deterioration or structural damage. The evaluation of integrity of existing concrete structures has been carried out through several testing methods and procedures such as non destructive test (NDT) and partially destructive test using sophisticated testing techniques. However, the criteria of selection for suitable testing method and techniques is still are being unclear depending types of structure that need to be tested. The criteria determination of most suitable codes and standards specification for Malaysia perspective is also unclear. Therefore, it is vital to study the reality in selecting most suitable testing method incorporated with most suitable codes and standardizations to carry out integrity test on existing concrete structures in Malaysia.
Konkrit merupakan di antara bahan bina yang sering digunakan di dalam projek kejuruteraan awam di Malaysia. Di antara alasan penggunaanya adalah faktor ekonomi dan keperluan pembaik pulihan yang rendah sepanjang tempoh keboleh khidrnatannya. Walau bagaimanapun, konkrit mengalami beberapa kerosakan dan kemerosotan sepanjang hayatnya kerana kekurangan pengetahuan pada sifat dan kelakuannya. Dengan mengunakan teknik-tehik untuk pemeriksaan kualiti konkrit bagi struktur yang sedia ada ama ada ujian separa musnah ataupun tak musnah, kualiti konkrit yang hendak diuji boleh dikenalpasti. Namun, dalam persepti Negara kita, criteria untuk mengenalpasti ujian konkrit bagi tujuan kajian tertentu masih tidak ada definasi dengan mengambil kira kod-kod specifikasi yang tertentu. Maka, adalah pentingnya untuk membuat kajian untuk mengenalpasti criteria untuk pilihan ujian konkrit mengikut kod- kod specifikasi tertentu untuk mengenalpasti ujian yang terbaik untuk pemeriksaan kualiti struktur konkrit yang sedia ada.
Kajian ini termasuk membuan ujian konkrit yang dipilih iaitu "Schmidt rebound hammer", "Ultrasonicpulse velocity'' dan "core test". Kajian in telah dilalukan atas jambatan yang sedia ada di Pelabuhan Klang. Segala keputusan akan ditafsirkan mengunakan bentuk jadual dan graf untuk analysis.
Data
kajian juga telah dibezakan mengunakan kod-kod specifikasi yang dipilih untuk mendapatkan perbezaan dalam penerimaan data untuk tujuan analisis. Kajian juga dilalukan dalam bentuk temurah dengan pakar jurutera yang berpengalaman dalam bidang kajian konkrit mengunakan boring sod selidik. Segala keputusan temuramah di pamerkan dalam bentuk jadaul dan graf. MelaIui kajian ini, mendapat tahu bahawa, ujian "concrete core" memberikan datarrrr
2.2.2.4 Determination of Pulse Velocity 21
2.2.2.4.1 Transducer Arrangement 21
2.2.2.4.2 Determination of Pulse Velocity by Direct
Transmission 23
2.2.2.4.3 Determination of Pulse Velocity by
Semi-Direct Transmission 23
2.2.2.4.4 Determination of Pulse Velocity by Indirect
or Surface Transmission 24
2.2.2.4.5 Coupling the Transducer onto the Concrete 25
2.2.2.4.6 Factor Influencing Pulse Velocity
Measurements 27
2.2.2.5 Determination of Concrete Uniformity 31
2.2.2.6 Detection of Defects 32
2.2.2.7 Examples of Relationships between Pulse
Velocity and Compressive Strength 33
2.3 Partially Destructive Test
2.3.1 Concrete Core Test
2.3.2 Cores vs. Cylinders
2.3.3 Coring Direction
2.3.4 Top-to-Bottom Strength Variation
2.3.5 Consolidation
CHAPTER III
2.4 Codes, Standards and Specifications 41
2.4.1 General Considerations 42
2.4.2 Different Categories of Standards 43
2.4.2.1 Standards 43
2.4.2.2 Codes and Specifications 43 2.4.2.3 Other Types of National Documents 44 2.4.2.4 Standardisation Organisations and Some of the Standards Relating to Testing of Concrete 44 2.4.2.4.1 American Society for Testing and Materials
(ASTM) 44
2.4.2.4.2 British Standards Institution (BSI) 46
METHODOLOGY
3.1 Introduction 48
3.2 Document Study 49
3.2.1 Concrete Core Test 49
3.2.2 Schmidt Rebound Hammer Test 51 3.2.3 Ultrasonic Pulse Velocity Test 52 3.3 Interview with Civil and Structural Consulting Engineers
Using Questionnaire 53
3.3.1 Contents of the Questionnaire 53 3.4 Comparison of Cube characteristic Strength using
LIST OF TABLES
TABLE NO TITLE
Effect of temperature on pulse transmission
Effect of specimen dimensions on pulse transmission
Classification of the quality of concrete on the basis of
pulse velocity 30
Rebound Hammer Test Results
Measurement for Rebound Hammer UPV Test locations on
the T-Beam
Ultrasonic Puke Velocity Test Results
Concrete Core Compression Test Results
Estimated In-Situ Strength throughout Interpolation fiom
Correlation Curve
Estimated In-Situ Cube Strength for all three types of test
Comparison of Cube characteristic Strength using BS 1881&
BS 6089 and BSEN 13791:2007 E m Codes
Variance between there types of test conducted
Variance between BS 1881 and BSEN 13791
LIST OF FIGURES
FIGURE NO TITLE
1.1 Research Methodology Flow Chart
2.0 Schmidt Rebound Hammer
2.1 A cutaway schematic view of the Schmidt rebound hammer
2.2 Relationship between 28 day compressive strength and
rebound number for limestone aggregate concrete obtained
with Type N-2 Hammer
2.3 Correlation curves produced by different researchers.
(Greene curve used Type N hammer; others used Type N-2).
2.4 Effect of gravel from different sources on correlation curves.
2.5 Comparison between correlation curves for crushed
limestone and siliceous
2.6(a) Direct Transmission
2.6(b) Semi-direct Transmission 2.6(c) Indiuect or surface transmission
2.7 Pulse velocity determinations by indirect (surface) transmission
2.8 Relation between ultrasonic pulse velocity and compressive
strength for concretes of different mix proportions
2.9 Planes of weakness under coarse aggregate particles due to
bleeding
2.10 Estimated within-member strength variations
2.11 Longitudinal resonance frequency of concrete cores
3.1 Photographs showing the process of concrete core sample testing
Photographs showing the process of Schmidt rebound
hammer testing 5 1
Photographs showing the process of UPV testing 52
Top View of T-Beam L=PBiPC-S2-EX-01 59
Side View of T-Beam L=PB/PC-S2-EX-01 59
Correlation Curve of UPV against Estimated In-situ Cube Strength 62
Factors Influencing in Selecting Method of Testing 64
Proportions of nature of test by respondents 65
Responses on Partially Destructive Test Preference 65
Responses on Partially Destructive Test Preference 66
Responses on selection of standard codes and practice for
CHAPTER I
INTRODUCTION
1.1 Introduction
Integrity test on existing concrete structures is often being carried out to
determine the assessment for the structure through several aspects such as to determine
the whether the structure is suitable for its designed use, for proposed change of usage or
extension of a structure, to ensure the acceptability of structure following to any
deterioration or structural damage such as caused by fue, blast, fatigue or overload and
to ensure the serviceability or adequacy of member known or suspected to contain
material which does not meet specifications or with design faults.
The fundamental of structural integrity and durability is to develop continuous
monitoring concepts for structural concepts for structural components and for the global
behavior. A structure is said to have general structural integrity if localized damage does
structural safety under ultimate and serviceability conditions and by ductility as well as
redundancy of load path.
The integrity of concrete structures can justify by using several tests available for
testing concrete range from completely non-destructive, where there is no damage to the
concrete, through those where the concrete surface is slightly damaged, to partially
destructive test, such as core test, and pullout and pull off test, where the surface has to
be repaired after the test. The range of properties that can be assessed using non-
destructive test and partially destructive test quite large and includes such fundamental
parameters as density, elastic modules, and strength as well as surface hardness and
surface absorbtionand reinforcement location, size and distance fiom the surface. At
times, it is also possible to check the quality of workmanship and structural integrity by
the ability of detects void, cracking and delamination.
The assessment of integrity of existing concrete structures should also taken into
consideration of requirements of several codes, standards, specification and procedures
established by most countries national bodies and relevant organizations. Standards can
play important role in international co-operation when they are used in contracts. The
growth in international trade has resulted in a growth in the need for International
Standards which can be acceptable compromise between different national standards.
1.2 Problem Statement
Integrity test on existing concrete structures is being implemented widely in
environments loading take place over time. The evaluation of integrity of existing
concrete structures has been canied out through several testing methods and procedures
such as Non Destructive Test
W T )
and partially destructive test using sophisticatedtesting techniques. However, the criteria of selection for suitable testing method and
techniques is still are being unclear depending types of structure that need to be tested.
The criteria determination of most suitable codes and standards specification for
Malaysia perspective is also unclear. Therefore, it is vital to study the reality in selecting
most suitable testing method incorporated with most suitable codes and standardisation
to carry out integrity test on existing concrete structures in Malaysia.
1.3 Research Objectives
The main objectives of this study are as per listed below:-
i. To identify the factors that influences in selecting the most suitable testing method
and procedures to conduct integrity test on existing concrete structures.
ii. To analyse and compare on selected codes of practice and standardization for
1.4 Research Scope
This case study scope will be focusing on testing methods and techniques on
existing concrete structures incorporated with comparison of codes of practice and
standardisation established by BS 1881, BS 6089 and BSEN 13791. This case study is
based on several concrete core results obtained from testing carried on existing bridge
concrete structures and pre-stressed concrete beams located in Klang Valley. The details
of the project will not be illustrated because the project contains certain confidential
statements.
1.5 Research Methodology
This case study will be consisting testing on existing concrete structures using
concrete core method, rebound hammer test and Ultra sonic Pulse Velocity (WV) on
existing concrete structures of an unnamed bridge in Klang Valley. Results will be
tabulated for comparison between BS 1881, BS 6089 and BSEN 13791. Results will be
analyzed using calculation for cube characteristic strength and design requirement and
acceptability of the results obtain from the tabulation and wrapped out with conclusion
and recommendations. Recommendations
will
be an overview on options forstrengthening the affected structures. The methodology flow chart are shown as below as
I
DEFINE THE PROBLEMI
SPECIFY THE OBJECTIVES
4
LITERATURE REVIEW
I
COLLECTING DATAI
DATA STUDY -Data obtained form Rebound Hammer Test, Ultrasonic Pulse Velocity and Concrete Core Sample will be analyzed and presented.
INTERVIEW
-Interview five experiences C&S consulting engineers using prepared
questionnaire.
COMPARISON
-
BS 81 10&BS 6089 cube characteristic strength and BSEN 137912007 cube characteristic strength.I
ANALYSIS AND RESULTSI
CONCLUSION AND RECOMMEND A TION
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