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  <title>DSpace Collection:</title>
  <link rel="alternate" href="http://dspace.dtu.ac.in:8080/jspui/handle/123456789/45" />
  <subtitle />
  <id>http://dspace.dtu.ac.in:8080/jspui/handle/123456789/45</id>
  <updated>2026-07-02T06:31:44Z</updated>
  <dc:date>2026-07-02T06:31:44Z</dc:date>
  <entry>
    <title>EXPERIMENTAL EVALUATION OF  SEISMIC RESPONSE OF NON STRUCTURAL COMPONENTS IN RC  FRAMES</title>
    <link rel="alternate" href="http://dspace.dtu.ac.in:8080/jspui/handle/repository/22936" />
    <author>
      <name>THAKUR, AKASH</name>
    </author>
    <author>
      <name>PAL, SHILPA ( SUPERVISOR)</name>
    </author>
    <id>http://dspace.dtu.ac.in:8080/jspui/handle/repository/22936</id>
    <updated>2026-06-25T05:07:24Z</updated>
    <published>2026-05-01T00:00:00Z</published>
    <summary type="text">Title: EXPERIMENTAL EVALUATION OF  SEISMIC RESPONSE OF NON STRUCTURAL COMPONENTS IN RC  FRAMES
Authors: THAKUR, AKASH; PAL, SHILPA ( SUPERVISOR)
Abstract: Non-structural elements (NSEs) such as cable trays, pipelines, HVAC systems, and &#xD;
suspended utilities are highly vulnerable during earthquakes and play an important role &#xD;
in maintaining building functionality after seismic events. Recognizing the importance &#xD;
of seismic safety of utility systems, IS 1893 introduced new provisions for &#xD;
“Architectural Elements and Utilities (AEUs)” in Indian seismic design practice. &#xD;
However, limited experimental validation is available for these newly introduced &#xD;
provisions. The present study investigates the seismic behaviour of cable tray systems &#xD;
installed in a structural frame model subjected to shake table excitation. Cable trays &#xD;
with rigid and flexible support configurations were installed at different floor levels, &#xD;
and acceleration response was measured at the base, floor slabs, and cable tray &#xD;
locations under excitation frequencies ranging from 0.5 Hz to 12 Hz. &#xD;
Experimental results showed significant floor acceleration amplification at upper &#xD;
floors, with maximum Peak Floor Acceleration (PFA) of 1.5g observed at the third &#xD;
floor. Resonance behaviour was observed between 6.5 Hz and 8.5 Hz, resulting in &#xD;
sudden increase in cable tray acceleration response. The amplification factor increases &#xD;
significantly with elevation, showing a 50.38% rise from the 1st to the 2nd floor and a &#xD;
further 25.00% rise from the 2nd to the 3rd floor, resulting in an overall increase of &#xD;
87.97% from the 1st to the 3rd floor. The flexible support system shows the highest &#xD;
amplification increase at the 1st floor (81.82%), while the increase at the 2nd and 3rd &#xD;
floors is approximately 53–59% compared to the rigid support system. &#xD;
Comparative analysis between experimentally obtained seismic forces and codal force &#xD;
predictions based on Draft IS 1893 and ASCE 7 indicated that actual seismic demand &#xD;
exceeded equivalent static codal predictions near resonance conditions. Where &#xD;
experimental force exceeded the IS 1893 value approximately 71%. The study &#xD;
highlights the importance of considering floor amplification, resonance effects, and &#xD;
support flexibility in seismic design of utility systems. The findings of the study &#xD;
contribute toward improved understanding of seismic behaviour of non-structural &#xD;
utility systems and provide practical design recommendations for seismic anchorage &#xD;
and support systems in RC buildings.</summary>
    <dc:date>2026-05-01T00:00:00Z</dc:date>
  </entry>
  <entry>
    <title>STRUCTURAL INTEGRITY ASSESSMENT  FOR LIFE EXTENSION AND  RETROFITTING OF AGING OFFSHORE  PLATFORMS</title>
    <link rel="alternate" href="http://dspace.dtu.ac.in:8080/jspui/handle/repository/22935" />
    <author>
      <name>GUPTA, PRANJAL</name>
    </author>
    <author>
      <name>PAL, SHILPA (SUPERVISOR)</name>
    </author>
    <id>http://dspace.dtu.ac.in:8080/jspui/handle/repository/22935</id>
    <updated>2026-06-25T05:07:15Z</updated>
    <published>2026-05-01T00:00:00Z</published>
    <summary type="text">Title: STRUCTURAL INTEGRITY ASSESSMENT  FOR LIFE EXTENSION AND  RETROFITTING OF AGING OFFSHORE  PLATFORMS
Authors: GUPTA, PRANJAL; PAL, SHILPA (SUPERVISOR)
Abstract: Hydrocarbons continue to play an important role in meeting global energy demand. &#xD;
In India, offshore oil and gas facilities, especially in the western offshore region, &#xD;
contribute significantly to domestic production and energy security. However, &#xD;
many fixed jacket platforms in fields such as Mumbai High are now operating &#xD;
beyond their actual design life and are exposed to long-term deterioration due to &#xD;
wave loading, corrosion, fatigue, accidental damage, and changing operational &#xD;
requirements. These factors make periodic reassessment and re-certification &#xD;
essential to ensure the continued structural integrity and safe operation of aging &#xD;
offshore platforms. &#xD;
The present study focuses on the structural reassessment of an existing fixed jacket&#xD;
type offshore platform based on the recommendations of the American Petroleum &#xD;
Institute (API) for life extension assessment. Site-specific metocean data for the &#xD;
Gulf of Kutch, including wave, wind, and current conditions corresponding to both &#xD;
operating and extreme storm environments, are considered during the analysis. A &#xD;
global linear in-place structural analysis is performed using SACS v24 to evaluate &#xD;
the adequacy of jacket members and tubular joints under combined operational and &#xD;
environmental loading conditions. Member and joint utilization checks are &#xD;
performed in accordance with API RP 2A, 22nd Edition, Working Stress Design, &#xD;
2014 provisions to identify overstressed structural components. &#xD;
For loading conditions where the platform does not meet the prescribed acceptance &#xD;
criteria, a nonlinear ultimate strength assessment is performed using static pushover &#xD;
analysis to capture the actual structural response under extreme environmental &#xD;
loading. Incremental wave loading is applied until structural collapse to investigate &#xD;
the failure sequence, redistribution of internal forces, and ultimate collapse &#xD;
behaviour of the jacket system. The Reserve Strength Ratio (RSR), also referred to &#xD;
as the Collapse Load Factor (CLF), is evaluated to determine the residual strength &#xD;
and redundancy of the platform. &#xD;
The study also examines strengthening and retrofitting techniques for overstressed &#xD;
subsea tubular joints, which remain one of the major challenges in rehabilitation of &#xD;
aging offshore structures. Retrofit schemes using ring stiffeners and friction-grip &#xD;
clamp systems are evaluated for strengthening deficient joints and facilitating &#xD;
iv &#xD;
member replacement without extensive modification to the existing structure. To &#xD;
investigate local joint behaviour in detail, Component-Based Finite Element &#xD;
Analysis (CBFEA) is carried out using IDEA StatiCa 26.0. Detailed finite element &#xD;
models of tubular joints incorporating ring stiffeners and clamp arrangements are &#xD;
developed to evaluate stress distribution, load transfer mechanisms, and structural &#xD;
performance under applied loading conditions. &#xD;
The results of the study indicate that the adopted reassessment and strengthening &#xD;
approach improves both global and local structural performance of the aging jacket &#xD;
platform. From the in-place analysis, 20 tubular joints are found overstressed under &#xD;
extreme storm loading. After grout filling, most of the joints meet the unity check &#xD;
requirement and for remaining critical joints retrofitting procedures are performed. &#xD;
The pushover analysis shows adequate global reserve strength, with the minimum &#xD;
RSR obtained as 1.80 against the required value of 1.60, and the maximum RSR &#xD;
obtained as 3.20. For the proposed mechanical friction-grip clamp, all IDEA &#xD;
StatiCa checks remain within allowable limits, with maximum bolt utilization of &#xD;
87.2%, weld utilization of 76.8%, and first buckling factor of 43.85. The ring &#xD;
stiffener model also shows improvement in local stress distribution, with the &#xD;
equivalent stress in members reducing from 355.3 MPa to 286.9 MPa. These results &#xD;
confirm that targeted retrofitting using ring stiffeners and friction-grip clamp &#xD;
systems can improve the residual capacity and support the life extension of the &#xD;
existing offshore jacket platform.</summary>
    <dc:date>2026-05-01T00:00:00Z</dc:date>
  </entry>
  <entry>
    <title>COMPARATIVE STUDY OF STATIC AND DYNAMIC ANALYSIS OF RCC STRUCTURES UNDER INDIAN SEISMIC CONDITION</title>
    <link rel="alternate" href="http://dspace.dtu.ac.in:8080/jspui/handle/repository/22932" />
    <author>
      <name>PORE, VISHNU</name>
    </author>
    <author>
      <name>Robert, B.R.G. (SUPERVISOR)</name>
    </author>
    <id>http://dspace.dtu.ac.in:8080/jspui/handle/repository/22932</id>
    <updated>2026-06-25T05:06:49Z</updated>
    <published>2026-05-01T00:00:00Z</published>
    <summary type="text">Title: COMPARATIVE STUDY OF STATIC AND DYNAMIC ANALYSIS OF RCC STRUCTURES UNDER INDIAN SEISMIC CONDITION
Authors: PORE, VISHNU; Robert, B.R.G. (SUPERVISOR)
Abstract: The increasing occurrence of earthquakes in different seismic regions has emphasized &#xD;
the necessity for reliable structural analysis methods in reinforced cement concrete &#xD;
(RCC) buildings. This study presents a comparative evaluation of static and dynamic &#xD;
analysis techniques for RCC structures under Indian seismic conditions. The goal of &#xD;
the research is to explore the structural behavior, seismic performance, and response &#xD;
characteristics of RCC buildings when subjected to earthquake forces as specified in &#xD;
Indian seismic design provisions, primarily based on Bureau of Indian Standards code &#xD;
recommendations such as IS 1893 and IS 456. &#xD;
In this research, multi-storey RCC structures are modeled and analyzed using ETABS. &#xD;
Pushover analysis and time history analysis, are used to assess the seismic response of &#xD;
the structures. Important response parameters such as storey displacement, storey drift, &#xD;
base shear,  are compared for  seismic zones  IV . &#xD;
This dissertation presents a detailed comparative study of the pushover analysis of &#xD;
RCC structures with rigid joints under Indian seismic conditions. The primary aim of &#xD;
the study is to evaluate, compare, and interpret the nonlinear seismic behavior of &#xD;
multistorey RCC buildings by considering key performance parameters such as base &#xD;
shear, terrace displacement. The buildings are designed in accordance with the &#xD;
provisions of IS 456:2000 for reinforced concrete design and IS 1893 (Part 1):2016 for &#xD;
earthquake-resistant design of structures. The seismic performance is assessed using &#xD;
the concepts of performance-based seismic design as defined in international &#xD;
guidelines such as FEMA 356 and ATC-40. &#xD;
For the purpose of analysis, three-dimensional numerical models of RCC buildings  &#xD;
are developed using ETABS software. Gravity loads and seismic loads are applied as &#xD;
per Indian Standard codes. Nonlinear hinge properties are assigned to beams and &#xD;
columns to simulate realistic material behavior under increasing lateral loads. The &#xD;
pushover analysis is carried out by applying incremental lateral load patterns in both &#xD;
principal horizontal directions until the target displacement or collapse mechanism is &#xD;
achieved.  &#xD;
A comparative assessment of different structural configurations is performed to &#xD;
investigate their influence on seismic behavior. The study highlights how changes in &#xD;
stiffness, strength, and ductility affect the overall performance of RCC structures. &#xD;
Storey-wise displacement, drift ratios, and plastic hinge distribution patterns are &#xD;
critically examined to identify vulnerable zones and potential failure mechanisms. &#xD;
ix &#xD;
Special emphasis is placed on understanding the nonlinear response characteristics of &#xD;
rigid jointed RCC frames, which are extensively used in Indian construction practice. &#xD;
The results obtained from the analysis clearly demonstrate that PA is highly effective &#xD;
in capturing the progressive damage behavior and post-elastic response of RCC &#xD;
buildings, which cannot be adequately assessed through linear static or dynamic &#xD;
methods. The study reveals that the formation and progression of plastic hinges follow &#xD;
distinct patterns that govern the ultimate collapse mechanism of the structure. It is &#xD;
observed that structures designed strictly as per code provisions still exhibit significant &#xD;
nonlinear deformations under severe seismic excitation, emphasizing the importance &#xD;
of performance-based evaluation. &#xD;
The outcomes of this study provide valuable insights into the seismic performance of &#xD;
RCC buildings under Indian seismic conditions and confirm the reliability of pushover &#xD;
analysis as a practical and efficient tool for seismic evaluation. The findings of this &#xD;
research are expected to assist structural engineers in identifying seismic deficiencies, &#xD;
improving structural configurations, and adopting safer design practices. The study &#xD;
also highlights the importance of incorporating nonlinear analysis procedures into &#xD;
routine seismic design and assessment workflows to enhance the safety, resilience, and &#xD;
sustainability of reinforced concrete structures in earthquake-prone regions of India.</summary>
    <dc:date>2026-05-01T00:00:00Z</dc:date>
  </entry>
  <entry>
    <title>INFLUENCE OF CORE ECCENTRICITY ON THE P-DELTA SENSITIVITY OF TALL REINFORCED CONCRETE BUILDINGS</title>
    <link rel="alternate" href="http://dspace.dtu.ac.in:8080/jspui/handle/repository/22930" />
    <author>
      <name>DIAMOND, VAIBHAV</name>
    </author>
    <author>
      <name>Robert, B.R.G. (SUPERVISOR)</name>
    </author>
    <id>http://dspace.dtu.ac.in:8080/jspui/handle/repository/22930</id>
    <updated>2026-06-25T04:59:40Z</updated>
    <published>2026-05-01T00:00:00Z</published>
    <summary type="text">Title: INFLUENCE OF CORE ECCENTRICITY ON THE P-DELTA SENSITIVITY OF TALL REINFORCED CONCRETE BUILDINGS
Authors: DIAMOND, VAIBHAV; Robert, B.R.G. (SUPERVISOR)
Abstract: In this thesis, we deal with the effects of P-delta on tall buildings which &#xD;
have core eccentricities and load irregularity in them. Seismic &#xD;
performance of buildings can also be greatly affected by this phenomenon. &#xD;
A regular planed high-rise building is taken in this project and with help &#xD;
of shear walls eccentricity is introduced in the structure. To study the &#xD;
isolated effect of eccentricity and P-delta, all the other parameters such as &#xD;
size of members, grid spacing, loading and material properties were kept &#xD;
constant. Multiple models were created with P-delta effect on and off so &#xD;
as to get a better understanding of second order effects on high-rise &#xD;
buildings. &#xD;
Building was created over 50m so as to meet the criteria of tall buildings &#xD;
according to IS CODE 16700: 2023. Grid spacing was kept at a constant &#xD;
of 8m with secondary beams provided to lessen the slab length. Material &#xD;
was kept M30 in all the members and models throughout the length and &#xD;
height of the building. &#xD;
This study compares responses like Maximum storey displacement, &#xD;
Storey drift, Torsional moment about Z-axis, Overturning moment and &#xD;
time period of different models. The results indicate that as the eccentricity &#xD;
is increased in the structure and load irregularity increases, the torsional &#xD;
moment and displacement of top storey is considerably increased under &#xD;
P-delta effect. Buildings with more centrally located cores show much &#xD;
more balanced response to the lateral forces such as Earthquake. We have &#xD;
used Response spectrum method to monitor the seismic performance of &#xD;
the building/ models.</summary>
    <dc:date>2026-05-01T00:00:00Z</dc:date>
  </entry>
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