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Repair and Strengthening of Underground Structures
Article · December 2009
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
REPAIR AND STRENGTHENING
OF UNDERGROUND STRUCTURES
Dr. Mohsen F. Shuaib
Tech. Manager of Conclinic Arabia, Assoc. Prof. in Minofeya Univ.
Eng. Hassan H. Ibrahim
G. Manager of Shade Contracting Company
Eng. Ahmad Abbass
Manager of Road Dept., Al-Naim Office
KEYWORDS: Maintenance, Repair Concepts, FRP, Decision Making
ABSTRACT: In this paper, maintenance and inspection programs are presented briefly. This paper
describes various methods for repairing specific deficiencies in structural elements within
underground structures. Water infiltration is the most common cause of deterioration. However,
deficiencies could be the result of substandard design or construction, or the result of unforeseen or
changing geologic conditions in the ground that supports the tunnel. Another common reason for
repairs is the fact that many tunnels have outlived their designed life expectancy and therefore the
construction materials themselves are degrading. Due to the fact that there are different causes for
the degradation, the method of repair could vary from one case to another. Some major structural
deficiencies for underground structures are displayed. In addition, a detailed explanation of the
different types of concrete deficiencies and methods for their repair is provided. Some practical case
for underground structures repair are described including expansion joint leakage, and the use of
advanced composite material or fiber reinforced polymer (FRP) for repair and strengthening.
Finally, multi-criteria decision making tools for repair of tunnels are presented briefly.
1 INTRODUCTION
Tunnel management system plays an essential role throughout the tunnel life including : design;
construction; operation; planning for maintenance, repair and rehabilitation (MR&R); optimizing
the allocation of financial resources, and increasing the tunnel safety. The first US national tunnel
management system (TMS) stated in 2002, while the national bridge management systems (BMS)
started early at mid of the 20th century. Structural deficiencies represent the greatest danger of all
potential underground structures failures for disruption of community welfare and possibility of
the loss of life. Maintenance programs aim to safeguard structural integrity; and to avoid
deterioration which may lead to more costly work. In this paper, maintenance and inspection
programs are presented briefly. Some major structural deficiencies for underground structures are
displayed including leakage of water, steel rebar corrosion, cracking of the structure and design
faults. The use of advanced composite material or fiber reinforced polymer (FRP) for repair and
strengthening. Multi-criteria decision making tools are presented at end of the paper.
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
TUNNEL MAITENANCE PROGRAMS
The maintenance program should be designed to include prevention of deterioration and damage;
prompt detection of deficiencies; and early accomplishment of maintenance and repairs to prevent
interruptions of transportations or limitation/restrictions of tunnel use as presented in Figure 1 (Chinh
2004).
Figure 1. Effect of maintenance on structural condition of tunnels
The main elements of tunnel maintenance programs are the inspection and the maintenance and Step
by Step Inspection, analyzing, and recommendation for tunnels is shown in Figure 2 (ITA 1991).
Inspection
Inspections of tunnel are classified as follows (Shuaib 2006): initial inspection; routine inspection;
damage inspection (emergency inspection); in-depth inspection; and special Inspection.
Maintenance
Maintenance of tunnels is the scheduled work that is required to preserve the tunnel condition.
T h e maintenance is divided to routine maintenance like sealing concrete; preventive maintenance
such as filling cracks; and major maintenance like water leakage and crack repair.
Figure 2. Step by Step Inspection, analyzing, and recommendation for tunnels
Preventive maintenance of structures system should include: washing/cleaning; inspection;
maintenance; and testing of the following elements (Shuaib 2006a):
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Tunnel lining structures
Tunnel finishers /claddings
Ventilation tunnel
emergency way
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Anchors and mechanical supporting
Drainage system in tunnel
Roadway structures in road tunnel
Structural system of railway
Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Preventive maintenance of equipment systems in tunnels are subdivided into mechanical system and
electrical system. The preventive maintenance of these systems must be complied with specialist
rules and manufactures suggested preventive maintenance procedures.
3 TUNNEL INSPECTION PROGRAM
Tunnel inspection program is a multi stage process, which may be categorized in the following
different tasks which may occur during routine inspection works (US-DOT 2005).
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Inspection Management.
Inspection and Condition Assessment.
Reporting.
Report Distribution and Archiving.
4 CAUSES OF TUNNEL DEGRADATION
This section outlines major causes of deficiencies in structural elements within a tunnel. These
defects must first be evaluated to determine the cause and the severity of the deterioration, in order to
select the best repair method. Many concrete linings in highway tunnels have an additional tunnel
finish which may hide the extent of the deterioration. Therefore, a repair analysis will need to
account for the replacement or repair of the finish as well. Deterioration in tunnels may be caused by
any of the various factors listed below (US-DOT 2004).
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Water Infiltration
Cracked and separated joints
Lack of tightness
Design or construction mistakes
Corrosion of embedded metals
Thermal loads Effects
Longitudinal spreading of foundations
Longitudinal differential settlement
Swelling soil and invert damage
Spall of tunnel crown joints.
Loss of support due to erosion
Seismic load and shape distortion
Ingress of dissolved gases
Steep fill slopes above tunnels
Changing of geologic conditions
Poor Workmanship
Deterioration of mortar
Degradation in concrete strength
Longitudinal loads on tunnels
Chemical action on lining
Damage to surface finishes
Clogging drainage due to fines
Cracks in track/road slab
Inclined tension cracks at the base
Differential movement at crown
Damage in repair system
Some defects in tunnels are presented in in Figures 3, 4, and 5 (Conclinic 2007).
Figure 3. Water leakage in tunnels and underground structures
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Figure 4. Concrete deterioration due to carbonation, alkali-aggregate reaction, and sulfate attack
Figure 5. Longitudinal cracks in tunnels and underground structures
REPAIR CONCEPTS OF TUNNELS
Method of repair could vary due to the fact that there are different causes for the degradation. The
applied repair methods must be durable, easy to install, capable of being performed quickly during
non-operating hours, and cost-effective. Factors affecting the repair method are the deterioration
severity, and the structural impact of the defect. The cause of the defect should be determined before
and remedial works, otherwise the same problem may repeat itself.
Repair priority definitions may be classified as follows (Chinh 2004);
 Critical: if it requires “immediate” action
 Priority: when interim or long-term repairs should be undertaken on a priority basis
 Routine: for that can be undertaken as part of a scheduled maintenance program.
Repair of defect in a tunnel could be divided in the following steps (ACI 224.1R 2007):
 Evaluation of damage/defect
 Relating observation to causes
 Selecting appropriate methods and
materials
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Preparation of drawing and specification
Selection of a contractor
Execution of the work
Quality control and acceptance
REPAIR FOR WATER INFLITERATION
a- Cause of Water Infiltration
Water infiltration is the main cause of deterioration of the tunnel structure. Tunnels can develop
leaks due to inadequate connection/joint design, substandard construction, and deterioration of the
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
waterproof lining. Most tunnels are designed with drainage mechanisms around the exterior of the
lining or embedded within the joints. As ground water flow patterns change over time a due to the
accumulating effects of basements of surrounding buildings, drains become clogged with sediment,
the water is bound to find its way into the tunnel through joints or structural cracks. Another scenario
is that a tunnel which was designed to be above the water table, is subjected to hydrostatic forces that
it is unable to resist and subsequently water infiltration becomes a problem.
b- Repair of Water Infiltration
Water infiltration repair must be investigated in the following zones (US-DOT 2005) :
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The surrounding ground
Interface between ground and lining
Tunnel Lining Structures
The lining intrados
Internal useful spaces of the tunnel
Remedial works for water infiltration inside tunnels could be a short term solution, a long term
solution and partial or full replacement of the tunnel lining. To determine the most cost efficient
method of repair for a particular situation, a specific cost analysis should be performed that considers
the costs over the life of the tunnel (ITA 1991).
b.1 Short Term Repair
This is a temporary or permanent solution by redirecting the infiltrated water to the drainage system
until further investigation can be performed and a more long term solution implemented. This
includes drainage toughs and using pipe network as shown in Figure 6 (Chinh 2004).
Figure 6. Short term repair of water infiltration
b.2 Long Term Repair
Many factors are involved in determining which long-term method should be used. These factors are:
site specific; cause of water infiltration, and water volume. A detailed study should be performed on
major leaks to determine source, amount of water leakage, and exact location of the leak. Some of
the long term repair methods are given below as shown in Figure 7 (Conclinic 2007),
 Insulated panels
 Waterproofing membrane
 Crack/joint injection
 Soil/rock grouting (back-wall grouting)
 Crack/joint repair (ACI 503.7 2007)
 Segmental joint repair
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Figure 7. Long-term repair of water infiltration by waterproofing, and injection methods
b.3 Structural Replacement
Lining reconstruction has advanced to a point where repairing numerous localized areas of the liner
becomes cost prohibitive. Reconstruction could include shotcrete or pumping plasticized concrete
within a form liner. In addition, using an exterior drainage system in a tunnel below the ground water
elevation is normally not effective over the long term because of the ability for water to penetrate
very small cracks that develop between drains. Some of the available systems for extensive lining
reconstruction are mentioned below as shown in Figure 8 (Watson 2003) and (Conclinic 2007).
 Shotcrete applications
 Joint control
 Water tight concrete
Figure 8. Shotcrete , and joint control by re-injection system
b.4 Joint Leakage Repair
Existing Repair systems for water leakage repair includes the following items:
(1) Types of Repair Materials
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(2) Types of Repair Methods
Water-based epoxy
Poly Urethane grout
Cementit ious grout
Acrylic grout
Combined cementitious polymer grout
 Injection system (Epoxy, PU)
 Surface treatment system
(cementitious)
 Surface filling systems
 (Polymer cementitious)
(3) Problems of Repair Systems
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Low adhesion to the wet surface (epoxy, urethane)
Improper hardening in a wet condition
Water absorption (Urethane)
Lack of movement of the substrate cracks by thermal change and vehicles (epoxy, cement)
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Polyurethane fume has failed as injection material for case of sea water or high sulfate salts in the
ground water (Kang et al. 2008), while acrylic grout is a durable leakage repair system as shown in
Figure 9 (Conclinic 2007).
Figure 9. Failure of polyurethane and success of acrylic for leakage repair system
CONCRETE REPAIR OF TUNNELS
Concrete deterioration in tunnels and concrete lining may be caused by various factors including:
water Infiltration, corrosion from embedded metal, thermal effects, loading conditions, and poor
workmanship. As concrete deteriorates, proper repairs shall help to avoid further degradation of the
structure.
a.
Corrosion Protection of Concrete
Concrete protection could be satisfied through construction areas and electrochemical/cathodic areas
as shown below (ACI 224.1R 2007).
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Design improvement (increase of cover thickness)
Material improvement (permeability using fly ash, slag, and silica fume)
Material improvement (Inhibitor using anoding or cathodic protection)
Concrete surface block (Painting, lining, sheet coating, and polymer mortar)
Rebar surface block (Coatings using fusion bonded epoxy and zinc coating)
Cathodic Protection
- Sacrificial Anode Method (No impressed current, low initial cost and reliable)
- Impressed Current Method
Corrosion protection of concrete Cathodic protection by sacrificial anode method consists of the
following items (Conclinic 2007) as shown in Figure 10.:
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Zinc mesh is used as a sacrificial anode
Glass Fiber Reinforced Polymer (GFRP) jacket for structure rehabilitation
Conductive mortar is used as a electrolyte solution
Corrosion sensors is used as a corrosion potential monitoring
Figure 10. Corrosion protection of concrete by sacrificial anode
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
b. Crack Repair of Concrete
Concrete and reinforced concrete lining crack repair is classified (US-DOT 2004) as shown in
Figure 11 (Conclinic 2007):
 Injection/grouting techniques
 Routing and sealing techniques
 Packing techniques
The selection of techniques or any combination is based on:
 Dimension, condition of crack
 Condition of concrete area need to repair
 Required target
Figure 11. Concrete crack repair by injection, sealant, and packing
c- Spall Repair of Concrete
Concrete and reinforced concrete lining crack repair is classified as shown in Figure 12
(Conclinic 2007) and (Newman 2001).
 Shallow spall with no reinforcement steel exposed
 Shallow spall with reinforcement steel exposed
 Deep Spall with reinforcement steel exposed
c.1 Repair of shallow spall with no reinforcement exposed is given below (Emmons 1994).
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Removal of loose or deteriorated surfaces
Clean the concrete surface
Sawcut on a 20-degree angle around the spalled area
Placing polymer repair mortar to original concrete depth
c.2 Repair of shallow spall with reinforcement steel exposed is as follows (Newman 2001).
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Removal of loose or deteriorated surfaces
Clean the concrete surface and the exposed steel rebar
Sawcut on a 20-degree angle around the spalled area
Coating rebars with anticorrosion agent compatible with the repair mortar
Placing polymer repair mortar to original concrete depth
Applying protective coat to the surface
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Figure 12. Repair of shallow spall with reinforcement steel exposed
c.3 Repair of deep spall with reinforcement steel exposed is as given below (Chinh 2004).
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Removal of loose or deteriorated surfaces
Clean the concrete surface and the exposed steel rebar
Sawcut on a 20-degree angle around the spalled area
Coating rebars with anticorrosion agent compatible with the repair mortar
Placing polymer repair mortar to original concrete depth
Applying shotcrete with additional welded wire fabric mesh WWF.
d- Seismic Strengthening of Tunnels
Tunnels were considered the safest structures under earthquake loads, the recent studies have
established that some damages have been observed in different tunnels and underground structures
during and after ground shaking []. Deformation modes and behavior of circular and non-circular
tunnels during earthquake are presented in Figure 13 (Hashash et al. 2001).
Figure 13. Behavior of tunnels during earthquake
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Seismic response of underground structures consists of three major steps as follows (El-Nahass et al.
2006).
1. Definition of the seismic environment and parameters
2. Evaluation of ground response to shaking
3. Assessment of structure behavior due to seismic loads
Application of advanced composite material can help in strengthening and retrofit of tunnels for
seismic resistance upgrade. Carbon and glass reinforced polymer (CFRP) and (GFRP) are used for
such purposes for its high tensile strength with light weight. The application of theses material is
shown in Figure 14 (Conclinic 2007).
Figure 14. Application of fiber reinforced polymer for strengthening of culverts
DECISION MAKING IN REPAIR
Tunnel management system (BMS) should provide a Decision Support System (DSS) which helps in
decision making for repair and rehabilitation of tunnels. Decision making is the study of identifying
and choosing alternatives based on the values and preferences of the decision making to choose the
one that best fits with our goals, objectives, desires, values, and so on. General decision making
process is as follows (Shuaib 2009).
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Establish goals
Identify alternatives
Define criteria
Assign decision matrix
Establish priority score matrix
Select a decision making tool
Preference ranking of alternatives
Sensitivity analysis
Final recommendation
Decision Matrix
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
Decision matrix combines both alternatives and criteria in one matrix to transfer the problem from
practical field to mathematical field as shown in Figure 15 (Shuaib 2009).
Criteria
C1 C2 ………………. CN
( w1 w2
……………wN)
Alternatives ______________________________
A1
a11 a12 ………………. a1N
A2
a21 a22 ………………. a2N
.
.
.
………………. .
AM
aM1 aM2 ………………. AMN
Figure 15. Decision matrix model
where, (Ai) is the alternatives, such as; repair using: Carbon Fiber Reinforced Polymer (CFRP), Fiber
Reinforced Polymer (FRP), Adding concrete element, adding steel plate and replacement of the
tunnel or part of it. ( i) = 1,2,3,…. M and (M) is the total number of alternatives. (Cj) is the criterion
on which a comparison is to be held between different alternatives such as; construction cost,
construction duration; traffic detouring cost; maintenance cost; ease of construction; future flexibility
and aesthetic appearance. (j) = 1,2,3,…… N; where (N) is the total number of criteria. (wj) is the
weight and importance of each criterion, which is estimated by the decision maker group such as:
the owner, the consultant office and public community representatives where ;
N
∑ w j = 1.0
(1)
j=1
(aij) is a measure or score of performance for each alternative subjected to each criteria. This measure
could be a quantitative type or a qualitative type. Qualitative types should be transformed to an
estimated quantity to handle decision making mathematically.
Priority Score Matrix
Each criterion has a different unit for measuring of (aij) such as US $, day,…elct. The decision
matrix should be formalized by normalization of each column of the matrix to find the modified
scores (bij) and to produce the dimensionless priority score matrix. Each column of the priority
decision matrix should satisfy (Eq. 2 ) (Shuaib 2009).
M
∑ (bij ) = 1.0
(2)
i=1
Decision Making Methods
There are several decision making methods such as: the weighted sum method (WSM); the weighted
product method (WPM); the analytical hierarchy process (AHP); the ELECTRE method; and
technique for order preference by similarity to ideal solution (TOPSIS) (Shuaib 2009).
(I)- Weighted Sum Method (WSM)
N
Pi =
∑ (b ij ) * wj
for i= 1,2,3… M
(3)
for i= 1,2,3… M
(4)
j=1
(II)- Weighted Products Method (WPM)
N
Pi =
∏ (100*b ij )wj
j=1
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Workshop of "Underground Structures in Hot Climate Conditions", 8-9 December 2009, Ministry of Transportation, Riyadh, Saudi Arabia
CONCLUSION
Tunnel management systems should be established carefully to increase the service life of tunnels.
Degradation of new tunnels starts from the first day of service of tunnels. Scheduled maintenance of
tunnels is required to preserve the tunnel condition. Water infiltration and water leakage represent
the major reasons for deterioration of tunnels. Efficient drainage system and waterproof of the tunnel
shall reserve tunnels. Regular repair of concrete and concrete lining are very essential for tunnels.
Corrosion protection and corrosion protection system could retard deterioration of concrete in
underground structures. The use of fiber reinforced material can help efficiently in strengthening and
seismic upgrade of tunnels us. Decision making in repair and strengthening of tunnels is complicated
issue but it could be modeled mathematically to use multi criteria decision methods for choosing the
most preferable alternative for repair of tunnels and underground structures.
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American Concrete Institute (ACI) Committee 503.7. (2007). Specification for crack repair by
epoxy injection. ACI, Farmington Hills, MI.
American Concrete Institute (ACI) Committee 224.1R. (2007). Causes, evaluation and repair of
cracks in concrete structures, ACI, Farmington Hills, MI.
Chinh, B.C. (2004). Maintenance and repair of underground works in Vietnam. ITA 30th General
assembly, Singapore.
Conclinic, Co. (2007). Total Solutions of Repair & Retrofit of the Facilities. www.conclinic.co.kr.
El-Nahas, F., Abdel-Motaal, M.A.& Khairy, A.T.H. (2006). Engineering of tunnels during
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Emmons, P.H. (1994) . Concrete repair and maintenance illustrated, R. S. Means Company, Inc.,
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Hashash, Y.M.A., Jeffrey J. Hook, J.J., Schmidtb, B. & Yaoa, J.I. (2001). Seismic design and
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