Neşeliler, Pınar

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Profile URL
https://hdl.handle.net/20.500.14365/7505
Name Variants
Neseliler, Pinar
Neşeliler, P.
Neseliler, P.
Job Title
Email Address
pinar.neseliler@ieu.edu.tr
neselilerpinar@gmail.com
Main Affiliation
06.01. Architecture
Status
Current Staff
Website
ORCID ID
0000-0003-2757-2853
Scopus Author ID
58111712400
Turkish CoHE Profile ID
B7D14FDD48FE44FD
Google Scholar ID
WVtp0LMAAAAJ
WoS Researcher ID
GSD-3278-2022
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pınarNeşeliler.jpg (10.8 KB)

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8

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3

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2

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2

Scopus Citation Count

2

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1

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1

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0.67

Scopus Citations per Publication

0.67

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1

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0

JournalCount
Intelligent Buildings International1
Journal of Building Engineering1
Proceedings of the International Conference on Education and Research in Computer Aided Architectural Design in Europe -- 43rd Conference on Education and Research in Computer Aided Architectural Design in Europe, eCAADe 2025 -- 2025-09-01 through 2025-09-05 -- Ankara -- 3447091
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Now showing 1 - 3 of 3
  • Thumbnail Image
    Article
    A Novel Adaptive Façade Using Cable-Driven Compliant Mechanisms
    (Elsevier, 2025) Neseliler, Pinar; Klamt, Marius; Akgun, Yenal; Blandini, Lucio
    Adaptive fa & ccedil;ade systems have the potential to significantly reduce energy consumption and CO2 emissions while enhancing, among others, the thermal and lighting comfort of building occupants. However, most existing adaptive fa & ccedil;ades rely on rigid body mechanisms, which introduce mechanical complexity and increase maintenance costs. To address these challenges, bio-inspired compliant mechanisms, which use flexible elements capable of elastic deformation, offer a promising solution by eliminating the need for conventional hinges. However, studies in the literature show that while such systems often succeed in reducing the number of hinges, they do not typically achieve a reduction in the number of actuators. This study addresses the gap by combining cable networks with compliant mechanisms to minimize the number of actuators while proposing a holistic approach that integrates kinematic design, material selection, pattern development, structural analysis, and daylight performance evaluation. The study uses computer simulations to evaluate the system's kinematic characteristics, material properties, structural integrity, and daylight performance. The study explores fa & ccedil;ade patterns, cable networks, and actuation systems, alongside structural and environmental analyses, to develop an efficient and innovative adaptive fa & ccedil;ade system that simplifies mechanical design and enhances visual comfort.
  • Thumbnail Image
    Article
    Citation - WoS: 2
    Citation - Scopus: 2
    Proposal for a Kinetic Façade System Based on Curved Line Folding Technique
    (Taylor & Francis Ltd, 2025) Neseliler, Pinar; Akgun, Yenal; Kavuncuoglu, Canberk
    The use of kinetic building envelopes creates an important potential for reducing carbon emissions and electricity consumption. However, a number of existing kinetic fa & ccedil;ades are made up of rigid body mechanisms, which require multiple actuators to move. This limits their feasibility in the construction industry due to the large number of required actuators. To address this issue, the curved line folding (CLF) technique offers an alternative design method that relies on compliant mechanisms rather than rigid body hinges. By using flexible elements to allow for elastic deformation, CLF reduces the complexity and number of actuators required to initiate movement. On the other hand, cable-driven systems have not been explored to actuate the CLF mechanisms. This paper aims to investigate an innovative fa & ccedil;ade model that reduces the number of actuators and complexity while initiating the movement of the systems based on the CLF technique and cable bending system. In this paper, firstly, the existing literature is examined. Then, the proposed kinetic fa & ccedil;ade system, its geometric properties, and actuation is introduced. Finally, a daylight simulation of the proposed system is run in Rhinoceros with the use of ClimateStudio.
  • Thumbnail Image
    Conference Object
    Smart Hinges Using Shape Memory Alloys for Architectural Applications
    (Education and Research in Computer Aided Architectural Design in Europe, 2025) Neseliler, P.; Turhan-Haskara, G.D.; Akgün, Y.; Maden, F.
    The objective of reducing energy usage in buildings has led to the development of adaptive and responsive systems that can respond to environmental changes in real time. Most responsive systems utilize rigid body mechanisms and electrically or pneumatically driven actuators. Actuation strategies are significant in designing adaptive facades since they are also in charge of energy consumption. Responsive systems can be integrated with smart materials capable of shape, color, and volume shifts in response to external stimuli change through material technology rather than relying on sensors, control systems, or active actuators. These smart materials, referred to as smart actuators, can be utilized to actuate systems. This study aims to present suggestions for a smart hinge for passive responsive shading structures using smart materials. The chosen smart material is nitinol wire, a shape memory alloy (SMA) with the ability to recall its preformed position. The methodology consists of two parts: an investigation of responsive systems composed of smart actuators and a proposal for a new smart hinge based on SMA utilizing Crane tool in Grasshopper. This paper shows the potential and constraints of smart actuators in architectural applications. The proposed smart hinge has the potential to contribute to the improvement of building envelopes through material technology. © 2025, Education and research in Computer Aided Architectural Design in Europe. All rights reserved.