Portfolio for MSc in Architectural Computation by pantelishadji

PORTFOLIO

PANTELIS HADJIGEORGIOU

M.Arch University of Cyprus

UCL APPLICATION

2024

Application ID Number: 24181825 Programme : MSc in Architectural Computation

ABOUT ME CONTACT

SUMMARY

Email : pantelishadji@outlook.com Address : 194 Bermondsey Wall East, London Behance : be.net/pantelishadji

I am an enthusiastic 5th year student at the University of Cyprus. I always find myself absorbed by architecture and wanting to improve and advance as much as possible. Technology is getting more integrated in the Architectural profession and using algorithms to assist generating complex designs is driving my passion for computational methods in architecture.

EDUCATION 2019 - NOW UNIVERSITY OF CYPRUS Integrated Master in Architecture (M.Arch) Current GPA : 8.97 IELTS : 8/9 2015 - 2018 HIGH SCHOOL, LATSIA LYCEUM Grade : 18.44 A-Level in Mathematics : A

PROFESSIONAL SKILLS AutoCAD Adobe Photoshop Adobe Illustrator Adobe InDesign C++

Twinmotion Rhino Grasshopper Sketchup

EXTRA-CURRICULAR SCOUTISM (2007-NOW) Out of the box thinking and overcoming obstacles. Orienteering, first aid and survival. Organisation skills and adapting. CYPRUS NATIONAL GUARD (2018 - 2019) Values of discipline, respect and punctuality. PHOTOGRAPHY CLUB (2020 - NOW) Creativity and attention to detail. Knowledge of architectural photography basics. STUDENT AMBASSADOR (2021 - NOW) Presentation and communication skills.

EXPERIENCE ARCHITECTURAL PHOTOGRAPHY SEMINAR 28 August - 1 September 2023 Grasped the basics of architectural photography. Frame and capture pictures of building. Post-production editing. Exhibited the best pictures at a ceremony. TEXAS A&M RESEARCH INTERNSHIP 1 June - 31 July 2023 Basics of topology optimisation (Fusion 360). Worked on active research for the department of Civil Engineering. Exhibited our research at a ceremony. Explored the local culture of Texas. ARCHITECTURAL CODING SEMINAR 15 June 2022 Introduction to Python and how to implement in Grasshopper. Basics of an essential programming language. J+A PHILIPPOU SUMMER INTERNSHIP 1 June - 31 July 2022 Actively monitored project timelines and trained on the multiple steps involved. Produced 3D Visualizations for a car dealership showroom. Created details of buildings for the quantity surveyor. J+A PHILIPPOU EXTERNAL CONTRACTOR 5 - 12 July 2021 Assigned to help with 3D Visualisation for the CFA Sports Centre. Created 2D drawings of the plans of the design.

CONTENTS PARAMETRIC BRIDGE A bridge created entirely by the use of Grasshopper, implementing minimal surfaces, providing flexibility and multiple variations of it with minimal work.

WINDLIPSE A technologically advanced skyscraper located in New York and uses the wind to shape its’ design. A modular design that is meant to be repeated as needed.

PRODUCTIVE AXES The region of Kaisariani offers a unique urban landscape which gives opportunities to develop and improve on the local community and redefine the regions autonomy.

STATIC ANALYSIS OF A HIGH-RISE BUILDING A project that allowed for some more in depth learning of different types of building skeletons. Design of a static system with multiple variations fully parametrically on Grasshopper and transfered to SAP 2000 to complete the static analysis.

HISTORIC TRAIN MUSEUM At an abandoned train station in Thessaloniki a lot could be done. Restoration of the station and repurposing as a museum for the train history of the area. A balance between the old and the new is created. Respecting the remains and differentiating the new structures.

REVIVING A NATURA 2000 AREA A neglected protected area that should have the protection of flora and fauna in its’ centre. A nature-centric design that provides solutions that will make nature thrive again both on land and sea.

CFA (KOP) SPORTS CENTRE Hired to produce drawings both 2D and 3D for the competition that J+A Philippou participated. Demanding workload with the entire team collaborating together.

RESEARCH ON 3D PRINTED WALLS On the two month internship I tried to grasp some ideas of topology optimisation, as well as ways to improve a wall in terms of thermal performance as well as materiality.

TOYOTA AND LEXUS SHOWROOM Participated on the 3D visualisations for an ongoing project of J+A Philippou I had the chance to be a part of. Designed 2D drawings for the quantity surveyor were also required.

PARAMETRIC BRIDGE Team work - Student project - Spring Semester 2021/22 - Dr. Kontovourkis Odysseas A bridge created entirely by the use of Grasshopper implementing minimal surfaces to produce multiple results. We had to provide flexibility and multiple variations while doing minimal changes. The course was divided into two parts . The first part included the creation of a minimal surface that was our unit. The second stage was the parametric creation of a bridge that included the unit and is capable to change the whole bridge shape as well as the unit shape and provide limitless variations. We got familiar with the powder printer and produced our final mockup with it. Keywords : Rhino, Grasshopper, Render, Powder printer, Minimal Surface, Parametric design, Computer-Aided Design

Deconstruct the surface from Rhino with the command Deconstruct Brep. Make the surface a mesh and connect the meshes together using the Weavebird command. Control the relaxation of the meshes use the command BouncySolver. The final result looks like the rectangular frame was a part of a bubble.

Bubbles provide the solution to an optimization problem. Bubbles assume the least surface possible which contains a certain volume. A bubble encloses the maximum amount of air given a certain amount of bubble solution.

Step 1

Step 2

Step 3

Step 4

Meeks Rosenberg doubly periodic surface

Grasshopper code for the unit. Steps and systems created from it.

Visualisation of an iteration of the bridge including the unit.

The general concept was to create a bridge which consists of two different paths from one side to the other while creating a new third path that leads to the highest point of the bridge and creates a viewpoint. On the algorithm, we created the bridge through the basics of a cuboid devided horizontally into 2 parts. Recalling points from the bottom, top, and middle of the cuboid gave as the flexibility to differentiate the height of our bridge accordingly. To achieve our desirable shape we had to take control of the hard and straight surfaces and distinguish cuboids that each unit would be later added. In addition, with the control of the individual points we now had the chance to control the elasticity of the structure and achieve the end result.

A couple of the proposed different Systems that include differentiation in the thickness, curvature, size, and height.

20 cm

25 cm

Part of the bridge that is printed and plan view on the printer plate.

Powder printer part of the bridge model.

WINDLIPSE Team work - Student project - Spring Semester 2021/22 - Dr. Phocas Marios, Dr. Savvides Andreas The buildings of New York have a huge impact on the environment and produce 50% of the total solid waste that appears in N.Y. leading to a more sustainable and environmental design. The project is a high-rise building that spans over 200m and takes advantage of the strong winds that occur as the building becomes taller and taller. A module by module concept is adopted with each module having different purposes both public and private. A thorough research concluded to an ellipse shape that will be able to take advantage of wind energy. A scale model measuring over one meter tall was created by utilising manufacturing methods. Keywords : High-Rise building, Sustainability, GFRC, Wind Turbines, Technical Details, Scale Model, 3D Printing

Site analysis of factors such as surrounding facilities, highline and pollution. Concepts leading to final design.

Exploded axonometric including multiple aspects of the project. I-Beams design and detail. Connections with the GFRC outer shell. Technical services per ellipse. Wind analysis and most beneficial location to put the wind turbines. Parametrically design the openings of the GFRC shell.

Bioclimatic diagrams for summer season on top and winter season below.

Indicative section of different uses co-existing.

Multiple plans of different uses.

Top left : Highline public space.

Top Right : Housing units.

Bottom left : Library.

Bottom Right : Seminar spaces.

Visualisation of the high-line level and the public uses of the space.

Scale Model manufacturing (3D printer, Laser cutter).

PRODUCTIVE AXES Team work - Student project - Spring Semester 2022/23 - Dr. Avramides Konstantinos, Mpalaoura Olga Kaisariani (Athens, Greece) is aunique location of great historical importance. It is admirable how WorldWar apartment complexes, two-floor houses and smaller apartment buildings coexist together. Taking into consideration the blank(empty) walls that exist in the area where tall buildings are next to small empty plots of land we wanted to create some appropriate uses. Adding vertical community farming is the one axis that the title refers to with the other one being the horizontal axis where facilities such as communal housing and kitchen are taking place. The autonomy of the whole project is essential and other than the initial expenses which are gonna be absorbed by European funds, that envolve the improvement of a community in a sustainable way, the project will be completely autonomous. Keywords : Parasitic structures, Circle Economy, Sustainability, Autonomy, Kaisariani, Community, Affordable

Economically challenged people

Locals

Housing Restaurant Renting Public Market

University Students

Study Space Housing

School Students

Restaurant

Communal Kitchen Vertical Farming

Seniors

Public Market Vertical Gardens

Users of our project aligned with facilities they will be using.

Circural Economy concept and how it will supply the project.

First block collage of public space next to the Community Kitchen.

Last block public garden next to the Kaisariani park .

Single floor housing

Single floor abandoned housing

Public green space

Two floor housing

Two floor abandoned housing

Selected site blocks

North facing empty wall Two facing empty walls Empty walls

Selected site blocks Single floor housing : 11 Single floor abandoned housing : 4 Two floor housing : 3 Two floor abandoned housing : 1 North facing empty walls : 9 Two facing empty walls : 3 Empty walls : 10

Axonometric to showcase vertical farming and squares

Plan of 2nd and 3rd block including housing public spaces and market spaces View of a public sidewalk leading to a square next to education spaces

STATIC ANALYSIS OF A HIGH RISE BUILDING Team work - Student project - Winter Semester 2023/24 - Dr. Phocas Marios A course with the purpose to understand more in depth the static analysis to create a high rise building. Knowledge of different types and mechanisms for high-rise buildings. We choce a hybrid system with pipe like core and tensile strings on the outside of the shape. Looking at a plan the shape is an octagon which has at the first and second iterations a diameter of 10m and at the third and forth iterations both a 10m and 6m diameter. The building is in total 96m with a floor every 4m. We use Eurocode 1 2005 as a standard and the GeometryGym plugin to easily transfer the model from Grasshopper to SAP2000. Keywords : Grasshopper, Rhino, SAP2000, High-rise building, Research, Metal Structure

Case study

Building structure

Cross-sections

Core (Circle cross-section )

Ο 1,5m thickness 0.4 m S 355

0.018 m

0.308 m

Σ3 ( 45o)

10 KN/m

Ο 1,5m thickness 0.4 m S 355

Radius (HEM 280)

0.018 m

S 235

Specifications of Cases 1 + 3

Grasshopper case 3

Secondary Cable Rods

Rhino Case 1

78.14 KN/m

10 KN/m

Ο 0,2m S 450 0.021 m

0.040 m

0.395 m

S 450

Horizontal Distributed Load

0.033 m

0.308 m

Diaphragm (HEM 360)

Vertical Distributed Load

0.288 m

Cable Rods 0.395 m

0.021 m

0.040 m

78.14 KN/m

Ο 0,2m S 450

Cross-sections

Octagons (HEM 280)

0.033 m

S 235

Building structure

Core (circle cross-section)

0.028 m

Cable rods Diaphragm (HEM 360)

Case study

0.031 m

Σ1

Radius (HEM 280)

Horizontal Distributed Load

0.310 m

Octagons (HEM 280)

Vertical Distributed Load

S 450

Ο 0,2m S 450

Rhino Case 3

HISTORIC TRAIN MUSEUM Team work - Student project - Winter Semester 2022/23(Erasmus) - Dr. Kotsopoulos Sofoklis A restoration design studio with a unique location. The abandoned train station which was functional for both travellers and businesses. At the first stage we were tasked to identify all the issues with the existing storage such as damp, holes, mold, wood rot and more. Site analysis was also an important part of identifing potential users entrances and transportation to and from the station. Complementary we had lectures discussing the ways a correct restoration is done. The design is done in a simple matter to easily differentiate between the existing and the new additions. Keywords : Restoration, Train station, Museum, Metal structure, History, Render

Structural Assembly of Analysis of our additions

Wall Panel Assembly

Visualisation of the entrance and public area

REVIVING A NATURA 2000 AREA Team work - Student project - Winter Semester 2021/22- Dr. Galvez Auxiliadora Maria An intense semester with a nature based design that gives priority to all the living organisms that are struggling in the area of Cape Greco (Ayia Napa). Corals, animals and plants used to thrive in this area and that is why it is protected by the Natura 2000 organisation. Throughout the years ignorance and the human factor destroyed millions of years of coral. Our task, to address both sea life and land life and minimise the human factor. Our design includes 3 parts, the floating wooden rafts, the natural land rocks and the seabed mud objects. Keywords : Natura2000, Nature revitilization, Technology, Flora and Fauna

Now

After 10 years

After 30 years

Sections of the effects of the placed natural rocks through time.

Visualisation of the area with the natural rocks that enhance nature and minimise transport invading the habitat.

Map of the structures locations as well as the way the structure will spread corals to locations that nature declined and died. Ceramics with corals that will grow and break the ceramics leading to grown corals spreading through the seabed and expanding the underwater ecosystem.

Visualisation of the floating coral restoration structures.

Visualisation of the object that will revitilise existing coral life.

CFA (KOP) SPORTS CENTRE COMPETITION Team work - Proffesional project - Summer 2022 - J+A Philippou As an external contractor i was given the opportunity to work with a large team on a tight deadline to create quality renders and plans of the already existing design. 3D Renders with the use of Twinmotion, and 2D maps with the use of AutoCAD and Illustrator. The project was for a competition for a new Sports Centre for the Cyprus Football Association that would accomodate both public spaces as well as facilities to house athletes temporarily for competitions. Keywords : Competition, Twinmotion, Plans, Visualisation

Visialisation of the view from the cafe space.

Plan of the facilities including cafe/restaurant the housing units as well as the football field.

Visualisation of the park area surrounding the football courts.

Visualisation of the cafe/restaurant and a section showing the housing units and the court boxes.

RESEARCH ON 3D PRINTED WALLS Team work - Research project - Summer 2023 - Texas A&M University Through the University of Cyprus we were given the opportunity to complete research as visiting students at the Texas A&M University. A once in a life-time experience for most as it is a distant destination. The team i was accepted in worked on 3D Printed Houses using not only conventional materials such as concrete but with new sustainable materials such as Hempcrete. I was tasked with learning more about topology optimization not only in architecture but in multiple industries. The end goal was to try and optimise a wall from a 3D Printed house to minimise the thermal conductivity as well as the weight. During the two month internship i was lucky to be guided by skillful researchers of the department. Keywords : Civil Engineering, Concrete 3D Printing, Hempcrete, Topology Optimization, Texas, Research, Fusion 360

Sergio Musmeci, Surreal Musceci Bridge

Topology Optimization, Thermal Performance and Sustainable Alternative for 3D-Printed Concrete Walls Pantelis Hadjigeorgiou a,b Sumedh Sharma, PhDc , Petros Sideris, PhDd,

Introduction

Topology Optimization

Thermal Performance

3D printing which was initially limited to manufacturing sector, has received significant attention from the construction industry and researchers in the past decade, leading to its application in large scale construction applications, by utilizing concrete and other cementitious and binder materials. Moreover, it also opens up opportunities to apply concepts of topology optimization, improvise cross-section to improve thermal performance and use innovative materials to improve sustainability.

The standard 3DPC wall for the prototype building was used as benchmark and optimized using Fusion 3601 for axial loading. The optimized shape was adapted to meet conventional 3D printing tool path.

The thermal performance for each wall variation was examined using Fusion 3601. The simulated result was used to identify the most inefficient cross-section of the wall assembly. R-values4,5 were calculated at these critical locations through standard code-based method.

The weight of concrete for the final printable wall was 26% less compared to the benchmark wall.

Objectives • Develop understanding on topology optimization, thermal performance 3DPC walls with infill patterns. • Apply topology optimization to increase mass participation of 3DPC walls. • Simulate thermal behavior of 3DPC walls. • Improve sustainability through introduction of hempcrete in 3DPC walls.

Conclusions

Methodology • Review of work on application of topology optimization on 3DPC wall. • Topology optimization of 3DPC wall using commercial application. • Compare reduction in CO2 emissions between 3DPC walls made using standard concrete and hempcrete. • Measure thermal performance of optimized 3DPC wall with standard concrete and hempcrete.

Topology Optimized: W= 353 Kg

Benchmark :W =1029 Kg

• •

Weight decrease of 26% from benchmark 3DPC to optimized printable 3DPC wall. The carbon footprint was eliminated completely from benchmark 3DPC to optimized printable hempcrete wall, while the optimized printable 3DPC wall had a reduction of 26%, due to the carbon footprint being associated with weight. The thermal performance improves by 20% from benchmark 3DPC to optimized 3DPC wall; and 38% from benchmark 3DPC to optimized wall printed using hempcrete.

•

Prototype Building Topology Optimized + 3D Printable: W= 768 Kg

• One story- residential type housing, 177 m2. • Location : Houston, TX • Max Temperature : 110 F

Based on this study, promising results were obtained through use of topology optimization and hempcrete as a print material :

Sustainable Alternative The 3D printed concrete in optimized wall was replaced with hempcrete to perform comparison on carbon footprint 2,3. The wall was checked for axial load capacity assuming the compressive strength of hempcrete to be 20% of standard printed concrete. There is a huge reduction in the Carbon Footprint of Hempcrete due to its nature. A significant reduction of 26% is achieved just by using topology optimization.

2.6 m

Acknowledgements • The University of Cyprus for the financial support and Texas A&M University for hosting undergraduate students as well as ARPA-E for the research opportunity. • Dr. Petros Sideris, Asst. Prof., Texas A&M University, Dr. Sumedh Sharma, Postdoctoral Research Fellow, Texas A&M University. • Daron, Kifah, Mohamed, Mohammad, Tal (Texas A&M University) for their valuable inputs and research discussion.

References 1. 2.

7.9 m

22.3 m

4. 5.

Samar, Verma Gaurav Malik. Autodesk Fusion 360&nbsp; (2nd edition). CADCAMCAE works, 2018. Dhir, Ravindra K., and Trevor G. Jappy. Exploiting Wastes in Concrete : Proceedings of the International Seminar Held at the University of Dundee, Scotland, UK on 7 September 1999. Thomas Telford EBooks, 1999. http://ci.nii.ac.jp/ncid/BA43614030. Magwood, Chris. 2016. Essential Hempcrete Contruction : The Complete Step-By-Step Guide. Gabriola, Bc: New Society Publishers. Iman Asadi, Payam Shafigh, Zahiruddin Fitri Bin Abu Hassan, Norhayati Binti Mahyuddin, Thermal conductivity of concrete – A review, Journal of Building Engineering, Volume 20, Pages 81-93, ISSN 2352-7102, 2018. Stanwix, William, and Alex Sparrow. The Hempcrete Book : Designing and Building with Hemp-Lime. Chicago, UIT Cambridge Ltd., 2014.

a. Visiting Exchange Intern, Texas A&M University, b. Undergraduate Student, Dept. of Architectural Engineering, UCY c. Postdoctoral Research Fellow, Zachry Dept. of Civil and Env. Engineering Texas A&M University, c. Asst. Professor, Zachry Dept. of Civil and Env. Engineering, Texas A&M University

TOYOTA AND LEXUS SHOWROOM Team work - Internship project - Summer 2022 - J+A Philippou When I joined the company as an intern for the summer of 2022 the project was in the final design phase which I played a major role producing renders and 2D Drawings. I had the opportunity to visit construction sites as well as produce drawings for the quantity surveyor and observe multiple projects that were happening at the same time. Different projects needed different skills but the team made me feel that i can achieve everything they needed from me. They were providing me with educational material for programs such as Revit and promoted the growth of every one of their employees. Keywords : Summer internship, 3D Visualisation, J+A Philippou, Car Showroom