Portfolio By
Øyvind Andreas Limi • Cand. Arch. • Graduated at:
KADK, Copenhagen •
Introd uc t i o n This portfolio contains two examples from my work as an intern at div. A. Arkitekter and Tegnestuen Vandkunsten. I’ve chosen projects where I have had responsibilities and produced work that I am able to reference. The substantial part of this portfolio on the other hand focuses on my work as a student at KADK in Copenhagen in order to produce an understanding of my development as an architect over the course of my education. These are also the projects I’ve been mostly submerged in and have developed the furthest in terms of the academic curriculum at my academy and at different study programs. Other work is merely referenced in my CV. The two projects from my time as an intern are the first to be presented and then my school projects are presented in a chronological order, starting with the oldest and ending with my master thesis.
Contact: name:
Øyvind Andreas Limi
mail:
oyvindlimi@gmail.com
tlf:
+45 52172647
linkedin:
Øyvind Limi
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C ontent
CV • Øyvind Andreas Limi, Cand Arch. 2016 P. 4 -5 Bodø Town Hall • div. A. Bodø, Norway, 2013
P. 6-9
Sustainable Social Housing • Vandkunsten, Lisbjerg, Denmark, 2014
P. 10-11
Climate Observation Outpost • Dep. 3, Black Rock Dessert, Nevada USA, 2011
P. 12-15
Water Treatment Plant • Dep. 2, Berlin, Germany, 2012
P. 16-19
Fire Station and Library • Dep. 2, Berlin, Germany, 2013
P. 20-29
Light Harvesting in Svalbard • AEE. Longyearbyen, Svalbard, 2014-15
P. 30-33
Analysis of Light Conditions • AEE. Longyearbyen, Svalbard, 2015
P. 34-37
Evaporative Cooling in the Amazon • AEE. Manaus, Brazil, 2015
P. 38-41
Bus and Ferry Terminal • AEE. Manaus, Brazil, 2016
P. 42-52
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CV “Throughout my studies I’ve been hardworking and focused on investigating and practising the skills and subjects concerning architectural creation, manifestation and representation through illustration and drawing, model making, film and photography, 3d modulation and text. I have done this with a mind to acquiring the skill set needed to practice as an architect as well as to expand my knowledge and understanding of architecture for personal and creative achievement. I am highly motivated as a student of architecture and I have been working creatively with form and imagery all my life. I perceive my choice to pursue a career in architecture to be a continuum of these interests and an opportunity to evolve these interests further and see their ultimate manifestation in built projects. I consider this to be both a privilege and a huge responsibility, and I am therefore always eager to learn new things and evolve my comprehension of architectural design.” - Øyvind Andreas Limi
Wo rk and Ex p eri e n c e 2016
A New Church in Sydhavn, Copenhagen • Open competition with Jens Thomas Arnfred
2014 - 2016 3xN • Model builder 2015
Cabin in Tynset • Realized project
2015
Log Structure • Smoking cabin, Tynset
2014
120 Hours, Øya Pavillion • Open competition with Hafstein Ævar Johannsson and Simon Nebelung
2014
Vandkunsten • 4 months internship
2013
Div. A. Architects • 3 months internship
2012 - 2013 Henning Larsen Architects • Model builder
E du c at i on 2014 - 2016
Master in Architecture • Program: Architecture and Extreme Environments, Institute for Building and Technology • School: The Royal Danish Academy of Architecture, Design and Conservation, Copenhagen
2010 - 2013
Bachelor in Architecture • Program: department 3 “Prosæs og Metode” and department 2 “Bygningen i Byen” • School: The Royal Danish Academy of Architecture, Design and Conservation, Copenhagen
2009
Norwegian and World History • University of Oslo, Oslo
2008 - 2009
Military Service • Navy, KNM Harald Haarfagre, Stavanger • Guard, Base Viken, Oslo and Akershus
2005 - 2008 Art and Creative Studies • Rosenvilde High School, Bærum
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P ro j e c ts Housing 2015 2015 2014 2014 2014 2014 2013
• Cabin, Tynset, Norway - Independent • Log Structure, Tynset, Norway - Independent • Parken, Førde, Norway - Intern at Vandkunsten • Sustainable Social Housing Competition, Lisbjerg, Aarhus - Intern at Vandkunsten • Bellahøj Renovation Competition, Copenhagen - Intern at Vandkunsten • Valby Apartments, Copenhagen - Intern at Vandkunsten • Cabin, Ål, Norway - Intern at div. A.
Education and Government 2014 • CBS Campus Competition 2013 • Town Hall Competition, Bodø, Norway 2013 • High School, Levanger, Norway 2013 • Tyin Club House Competition, Oslo
- Intern at Vandkunsten - Intern at div. A. - Intern at div. A. - Intern at div. A.
Culture 2016 2014
- Jens Thomas Arnfred - Collaboration
• A New Church in Sydhavn, Copenhagen • Scale,120 Hours Competition Entry, Oslo, Norway
Aquired Skills • Graphic Printing • Illustration and Drawing • Painting • Carpentry • Photography and Filming • Metal Working • Rapid Prototyping • Model Building
- Serigraphy, etching, lino
- Welding - Lasercutting, 3D printing, CnC milling
Language • Norwegian • English • Danish • Swedish -
Native Fluent Fluent Basic
Co mp uter C omp e t e n c e Adobe: • Photoshop • Illustrator • Indesign • Premiere • Aftereffects
- Highly Competent - Highly Competent - Highly Competent - Good - Familiar
Autodesk: • Autocad • 3D Studio Max • CFD
- Good - Familiar - Familiar
McNeil: • Rhino • Grasshopper
- Highly Competent - Familiar
Additional Software: • Sketchup • Vector Works
- Highly Competent - Good
Various Render Software: • V-ray - Good • Mental Ray - Familiar • Maxwell Render - Familiar
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Bodø Town Hall
Competition Team: C.Adams, O.H.Hiorth, H.Salvesen, Ø.A. Limi Location: Bodø, Norway
“The municipality announced an open architectural competition for a modern, flexible and energy efficient town hall. Our proposal is a solid, compact and rational building, designed as a public landmark, visible from much of the Bodø region and from the sea. The main internal circulation area consists of a continuous wood clad surface that connects the main entrance in the existing town hall with the new canteen at the top of the new building. All the new workplaces and public areas are connected to this main “artery”.” - www.diva.no
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Street View Render • Render of the proposed town hall with the existing building in the foreground
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Flow Diagram • The interior of the town hall is tied together by a big flow, imagined as a wooden carpet, underlying the flow and movement through the building while creating an informal social space
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Elevation East Facade • The elevation show how the proposal relates to the dimensions and formal gestures of the existing town hall
Elevation North Facade • The north side of the proposition extends all the way to the opposing road and creates a semi sheltered courtyard
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Sustainable Social Housing Invited Competition, 1’st price Team: Søren Nielsen, Mirjam Hallin, Kim Dalgaard, Øyvind .A. Limi Location: Lisbjerg, Aarhus, Denmark
This proposition for a new type of social housing strives to create a versatile and dynamic housing typology, one that unlike previous projects of a similar scale has a capacity for development over time and allows its inhabitants to move and change the configuration of the interior. Wood is chosen as the primary building material for its environmental qualities and organic materiality that will evolve with age to make the houses distinct.
Street View Render • This view was created by Mirjam Hallin and is included in my portfolio to illustrate the projects exterior qualities
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Rendered Interiors • The interiors are made from prefabricated modules of a solid wood composite material. Doors and Windows are made from Kebony
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Climate Observation Outpost 3’d Semester School Project By: Ă˜yvind A. Limi Location: Black Rock Desert, Nevada, USA
The harsh weather conditions on the Black Rock Dessert are challenging, but even more so with the absence of modern infrastructure and with its status as a nature reserve. This building is inspired by the black tents of the beduin people who face similar conditions, and have created for them selves moveable homes that are both cooling in high temperatures and isolating in cold periods. The most important ability of the black tent is however its resistance to strong winds and dessert storms. In a place like the B.R. Dessert where winds can reach speeds up to 75 m.p.h. These abilities are essential and I have adapted them to fit the needs of up to 6 scientists and the work they are meant to carry out in an energy efficient and sustainable way.
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Model Collage • This collage illustrates the tents position on the dessert plane and the environment it has to respond to.
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Section • Section showing the structural principle with its moorings and supporting cross section beams
Exploded Axonometric • Tent composition and supporting structure.
Three Layered Tent Structure • The outermost layer is a perforated skin that creates a shaded zone with reduced airflow • The intermediate zone provides a protected area and is designed to divert strong winds • The innermost zone provides the living quarters and is made of wool cloth to increase insulation
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Section • Section showing the extent of the structure
Model Picture • The model shows the structural quality of the design and how it is made up of three layers, creating three different zones for occupation
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Water Treatment Plant 5’th Semester School Project By: Øyvind A. Limi Location: Oberbaum Brucke, Berlin, Germany
The idea of a water treatment plant in the midle of Berlin was the result of investigations into the infrastructures and facilities that provide our cities with its sustaining functions. These mechanisms are often concealed and avoided as a visual or active part of our urban environment, and my project sought to bring one of these mechanisms, “the purification and distribution of water” out of confinement and into our interaction with the city by giving it an imprint that also serves a recreational purpose. The typologies and aesthetic quality of my project lend them selves from a rich heritage of structures concerning the distribution and supply of water, from ancient aqueducts to industrials dams and water towers. These structures where once prominent works of architecture and engineering in our built environment and therefore built accordingly with an aesthetic intension.
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Model View • Model picture of altered harbor edge with a step structure declining towards the water edge
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Section • Section of the basins and underlying vault that treat the wastewater at the end of the water distribution cycle
Elevation • Elevation of the water treatment facility with its water towers, pumping stations and water fall releasing surplus water into the river Spree
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Plan Drawing • Plan drawing showing the canal that provides the purification basins with water and then in turn the water towers and aqueducts
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Fire Station and Contemplative Library 6’th Semester Bachelor Project By: Øyvind A. Limi Location: Copenicker str., Berlin, Germany
This fire station goes beyond providing the functions that protects the city from fires and providing the firemen with what they need in order to do their job. This project is an attempt at creating a building where the combination of a library and a fire station is harmonious and a part of a single architectural vision, one that could not exist without either. In fact this project is not as much a fire station and a library, but the transition between the two and the architecture is the structure that enables it. The primary inspiration for this project have been the Benedictine monastery. In the traditional monasteries the everyday life of a monk was transformed into something holy through rituals and processions, strict rules and by the architecture in which they lived. The lowest floor is an open space covered by a huge roof. Without walls and supports for the ceiling the room is totally open and creates a flexible space where all of the fire stations essential functions are situated. The floors above are orientated around the atrium and become more and more enclosed by the construction as the elevation increases. The topmost floor is defined by a circular motion around the atrium which ends the passage that flows through the building leading to the different facilities. The space is distinctive because of its sole orientation inwards. It is entirely enclosed by facade elements and isolated from the outside world, a counterpart to the open and “extrovert“ first floor
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Model Picture of a 1:50 Working Model • Plaster panels make up the facade and are supported by a light weight structure attached to the columns and beams centred around the atrium.
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Model Study These models represent the transition from the conceptual investigation of two intersecting flows to the structure and shape that is the rational manifestation of the same ideas. Interior Views (page 23) These pictures show my working model and two different spaces I have been working with. It is only partly covered with facade elements in order to allow insight and registration of the effect the facade elements creates. 1 mm thick plaster screens are used to simulate the effect a semi transparent facade would have in the enclosed spaces of the library.
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Interior Views • 4th Floor, library • 3’d Floor, private quarters
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• 5. floor
• 4. floor
• 3. floor
• 2. floor
• 1. floor Plan Drawings • These drawings show how the different floors are organised and how their orientation increasingly turns inwards as you move upwards in the station
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Section Drawing • Coppernicker str. is at the right of the station and the river Spree is at the far left.
Plan Drawing with Context • The station is positioned at Copenicker str. with access to the road network. At the back is the public access to the library as well as a sheltered garden.
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Section Drawing • This drawing illustrates the scenarios that will unfold in the station and in the library, supported by the illuminating effects of the transparent facade and other openings.
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Section Drawing • This drawing shows the three primary orientations of the station. One is towards the street with the facilities supporting the activities of the fire station, while the private quarters of the firemen are oriented towards the garden in the back or upwards towards the secluded library
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Light Harvesting in Svalbard 7th Semester Field Research By: Ă˜yvind A. Limi Location: Longyearbyen, Svalbard, Norway
In January 2015, I participated in a expedition to Longyearbyen in Svalbard together with Architecture and Extreme Environments. The aim of the expedition was to get first hand experience and data from the arctic environment where temperatures are below zero and the sun never rises throughout the winter. We brought devices that we had developed and built for this purpose. Light is not only a part of our experience and perception of architecture, but it is a requirement in a building that we treat in the same way as we treat the need for insulation, ventilation etc. In order to meet the certain requirements we have to find solutions for increased or decreased light exposure. In Svalbard those solutions have to compensate for long periods of time with no sunlight at all. The traditional way has been to use artificial lightning. Artificial lighting will give the amount of illumination required for different purposes, but the quality of that light is questionable. Besides the purely practical application of natural light in buildings the use of these systems will make architecture and people perceptive to the changing cycles of natural light. The application of light in our architecture does not necessarily have to create static conditions in which we lose our intuitive understanding of our environment, but it might even enhance that understanding through curating and refining natural light sources within a spatial experience.
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Exbedition Picture • Device investigations in full moon light in Longyearbyen.
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Device Elevation • By using lenses that can be adjusted in any direction this device is able to focus and concentrate light from multiple light sources, static or moving. It allows for investigation into the qualities of light by creating a readable output for comparison and analysis. Furthermore it explores the potential in harvesting and enhancing natural light for use in architecture
Device Details and Collimator • A small lense with a diameter of 10 mm and with a focal length of 8.25 mm is positioned where its focal point and the focal point of the device intersect. This will collimate the light focused bye the device when adjusted correctly, meaning that light focused into a focal point that would otherwise be spread out in the opposing angle is refracted into parallel rays. The collimated light can either be reflected by a small mirror positioned at the back of the lense or transferred into a fiber optic cable, as in the top picture on page 33.
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Moon Tracking Picture Series
The pictures are taken with an interval of two minutes to capture the moons progression across the sky. The same progression is clearly visible on the circular screen where projected moonlight travel across its surface as the moon moves across the sky.
When the light reaches the end of the screen the lenses will have to be adjusted to capture the moonlight. This is achieved by simply sliding the lense along its rail, which is already aligned to the moon path, similar to an equatorial mount.
Picture Series of Device Investigations in Svalbard • In order to create a visual readout, a circular screen is fitted into the centre of the device, onto which captured light is projected. This is opposed to the collimator on the topmost picture, where light is directed into a fiber optic cable.
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Analysis of Light Conditions 8th Semester Project By: Ă˜yvind A. Limi Location: Longyearbyen, Svalbard, Norway
In preparation for a architectural project in Longyearbyen (see sketch) I conducted a thorough analysis of the light conditions on my site. The premiss of this analysis was that it would be detailed enough to inform a spatial and programatic project that would accommodate the need for illumination or shelter from it down to light conditions of a specific week, taking into account the level of sunlight and unique light phenomena like the cycle of the moon and the occurrence of northern lights. These factors relate to Longyearsbyen’s geographic position close to the north pole where the cycle of the sun spans multiple months and not 24 hours. This condition also provides Longyearbyen with extended hours of twilight with a luminous quality and length that present an architectural opportunity unique to this region and therefore necessary to map. Other factors necessary to understand are the influence of light pollution and air quality on my site. Longyearbyen is known for its astronomical observatories, but its light conditions are also delicate and air pollution and cloudy skies can enhance the light pollution from the city significantly in an environment otherwise derived of light sources.
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Sketch • Sketch of a proposal for a structure protruding from one of the old mines located at the side of one of the mountains surrounding Longyearbyen. • Great shutters and sliding openings are regulating the exposure to sun and moonlight as well as being able to reflect and divert light into the building.
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Sun, Twilight and Moon Diagrams • Diagrams showing light conditions represented by one day every week through out the year 2015 and the start of 2016
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Longyearbyen • Map of Longyearbyen showing its geographical characteristics and and its annual oscillations of different light phenomena. • Mine 1B has a superimposed digram of the light conditions of a specific day, showing how the mountains surrounding the city will block light coming from the moon or the sun when they’re at certain positions.
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Evaporative Cooling in the Amazon 9th Semester Field Research By: Ă˜yvind A. Limi Location: Manaus, the Amazon, Brazil
I have worked towards a design and a method that mimics natural processes of heat dissipation through evaporation and surface exposure to airflow. The mimicry is not a literal interpretation of trees or flowers but rather the manifestation of a principle derived from natural processes. That principle is plants and trees ability to evaporate water back in to the atmosphere through its massive surface are. These studies have been conducted with an aim towards reintroducing building principles that provide a higher thermal comfort, both indoors and outdoors, to an urban environment. One of the challenges Manaus is facing today is its alien building techniques that do not respond to the climate of the rainforest. Vegetated areas have decreased as the city has grown over the last century, and it has been replaced with concrete buildings and asphalted infrastructure that does little if anything to prevent flooding or to dissipate heat
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Deployment of Device in Manaus • Upon arriving in Manaus, 16 modules are assembled into a geodesic dome light enough to be carried around the city
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Module Composition • The modules are composed of three layers with a skin and three rails connecting them. A base layer fixes the module to the rest of the construction as well as the rails allowing the two subsequent layers to move. The outer layer (layer3) expands both fabrics and can be pulled to the full extent of the rails potentially maximising the surface area of the module. The middle layer is able to regulate the ambiguity between an exposed and confined “state” enabling the module to have an exposed outer surface and a retracted inner surface. This might be beneficial when retaining some water in a dry environment while creating cooling, or if the not so exposed inner layer induces more heat than it conducts away. Potentially it is pulled all the way back and maximises the surface area of the module, creating a double surface.
Isometric Detail Drawings of Expanding Modules • The two drawings show how the outer skin will expand with the retracting and extruding parts of the module.
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Temperature and Evaporation Investigations in a Forest Environment • Botanical Garden
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Location: 50°C 50°C Term. Pca. Matriz, 40°C 40°C Bus Station, 30°C 30°C Manaus Harbour 20°C
Temperature and Evaporation Investigations in an Urban Environment • Bus Station
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Bus and Ferry Terminal in Manaus 10th Semester Thesis Project By: Ă˜yvind A. Limi Location: Manaus, the Amazon, Brazil
This terminal building attempts at capturing and accommodating the events associated with the city and the river. This means that it has to respond to the annual floods of the river and other climatic conditions unique to the region like extreme heat and humidity as well as having to provide a spatially dynamic terminal that allows the narrative of the traveller to unfold as he or she moves through it. The Structures that make up the terminal is to be understood as a framework, defining, but not limiting the spaces you encounter as you move through the terminal building. The terminal will adapt to the changing conditions of the river and the city while preserving the flow of movement and establishing a continuous connection between the two. The connection between the city and the river is not necessarily one between the natural and the built environment, but a continuation of a infrastructure that consists of the internal modes of transportation provided by the city’s infrastructure and the greater infrastructure of the Amazon rive network. These two are in terms of cargo and intensity different and work on two different scales. The terminal building have to have the capacity for both. These challenges together with the environmental one’s is solved by a number of dynamic building components and solutions that are able to adapt and behave dynamically within the terminal structure.
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Sketch • Concept sketch illustrating the spatial framework of columns and pillars that occupy the harbor edge
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Area Exposed to Annual or Periodic Flooding Area Exposed to Annual or Periodic Draught
Plan and Context Drawing • Example of harbor configuration at a water level of 10 m
Plan 1 : 500 Master Project : Building with a Narrative
Bus and Ferry Terminal, Harbour Area, T0 Bus Station Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016
Plan and Context Drawing • example of harbor configuration at a water level of 30 m
Plan and Context Drawing • Example of harbor configuration at a water level of 20 m
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Flow and Access Diagram Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Flow Diagrams • The terminal structure allows for accessibility of an adversity of transportation and separate flows, favouring different modes of transportation in different parts of the terminal
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016
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Harbour Water Levels and Extension Diagram
Manaus, Bus and Ferry Terminal
Master Project : Building with a Narrative
Manaus, Amazonas, Brazil
Ă˜yvind Andreas Limi, stud 4733
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Water Levels of the Rio Negro • The water levels of the Rio Negro will fluctuate with almost 20 m every year, creating diametrical situations between flood and drought seasons
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AEE, IBT, KADK, Copenhagen
2016
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Main Terminal • The modular concept of pillars and arches creates an accessible and diverse space that occupies and transform the existing harbor edge.
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Isometric View 1 : 100 Master Project : Building with a Narrative
Main Terminal Area Manaus, Amazonas, Brazil
Manaus, Bus and Ferry Terminal AEE, IBT, KADK, Copenhagen
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Ă˜yvind Andreas Limi, stud 4733
2016
Bus Terminal • The structure of the bus terminal branches out in to the city and is composed of bus stops and minor constructions easily applicable and adaptable to the press of traffic and needs of its travellers
Isometric View 1 : 100 Master Project : Building with a Narrative
Main Terminal Area Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016
Detail Drawings and Diagrams • Exemplification of how the dynamic vision and intension of the terminal is manifested in the detailing of the construction and in the composition of the roof modules.
Isometric 1 : 10 _ 1:50 Master Project :
Building with a Narrative
Bus Stop and Roof Diagram Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016
Ferry Terminal • Ferries and boats dock at modular pontoons that are able to move with the rising or decreasing water levels. Accessibility is continuously provided by a sloping ramp protruding from the harbour edge
Isometric View 1 : 100 Master Project : Building with a Narrative
Harbour and Ferry Terminal Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016
Detail Drawings and Diagrams • Exemplification of how the dynamic vision and intension of the terminal is manifested in the dynamic structure and configuration of the docking points that have to respond to the three dimensional conditions of the harbor Isometric View 1 : 100 Master Project :
Building with a Narrative
Pontoons and Floating Piers Diagram Manaus, Amazonas, Brazil
AEE, IBT, KADK, Copenhagen
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Manaus, Bus and Ferry Terminal Ă˜yvind Andreas Limi, stud 4733
2016