Hatlehol Church
COLOPHON Title:
Hatlehol Church
Project module: Tectonic Design: Structure & Construction Period: 22. October - 16. December Group: 17 Semester: MSc01 ARC Supervisors: Claus Bonderup Dario Parigi Number of pages: 120 Number of prints: 9 Attachments: USB Drawing folder
_____________________________________________________ Casper Langberg Thaier
_____________________________________________________ Mathis Lauridsen Gerlich
_____________________________________________________ Melina Gode
_____________________________________________________ Nikoline Werngreen
_____________________________________________________ Piotr Zbierajewski
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ABSTRACT
The purpose of this project is to design proposal for a new church located in Hatlehol parish, in the eastern part of Ă…lesund, Norway. The project area has been studied through different analysis and have together with studies in Nordic architecture and tectonic been considered as the basis of the project. Site analysis indicated the importance of nature and terrain as fundamental aspects of the context. The tectonic approach has been made in relation to form, structure, materials and details and the Nordic approach was created with considerations about the nature on the site, the honesty in materials and simplicity. The design process started with the acoustic and structural system in the church room. From that point the focus was to create a plan, which was functional in all aspects of the clients needs. The aim in the project has been to create a new church, which could give identity to the town and function as a visual landmark, but more important a sacred environment assisted of the use of light, material and the architectural form.
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CONTENT Methodology 01 Analysis Site Introduction Surroundings Infrastructure Local nature Section Noise Climate Sun Precipitation The client Studies Nordic architecture Church of Norway Norwegian architecture Tectonic Acoustic Summary of analysis Vision Design criteria
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10 10 11 11 12 13 14 16 16 17 18 20 20 23 24 26 28 30 31 31
02 presentation Design concept Master plan Plan Sections Elevations Materials Outdoor Visualizations Structural Church room The rest of the building Details Cross section Detail A Detail B Detail C Detail D Detail G
34 35 36 37 42 44 45 46 54 54 56 58 59 60 61 62 63 64
Acoustic
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03 Design process Introduction Acoustics Structural Overall plan Detailing the sacred places Outdoor Conclusion
70 72 76 82 88 90 92
04 epilogue Conclusion Reflection References
96 97 98
05 Appendix Appendix 1 Appendix 2 Appendix 3 Appendix 4 Appendix 5 Appendix 6
104 106 108 109 112 117
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INTRODUCTION
This project has been developed in relation to the curriculum of MSc01 Architecture, Department of Architecture, Design and Media Technology at Aalborg University. The program of the project is based on a competition held in 2008. The project contains a proposal for a new church located in Hatlehol parish, in the eastern part of Ålesund, in Norway. The site is an undulating landscape containing wild nature with dense vegetation. The overall aim for the project has been to develop a design proposal with a tectonic approach and to achieve an innovative structural and architectural expression by ensuring a continuity and integrity of form, material, structure and construction. Furthermore, the aim has been to develop the Nordic craft tradition in relation to the new innovative design of the structure, use of materials and means for construction of modern architecture.
COMPETITION PROGRAM The competition program contains a description of the specific request and sizes for each function, which must be attached to the church as well as the functions around it. In addition there are also requests for the architectural expression of the church, both from the inside and from the outside. (Ålesund church fellesråd 2008) The church should: - Give identity to the town - Be a place for gathering in sorrow and in joy, despair and hope - Be a visual landmark in the landscape - Be a symbol of the meeting between people and spirituality
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METHODOLOGY The methodology behind the problem based learning method takes its starting point in a problem. This problem is then the fulcrum throughout the project. PBL results in a process composed of both theoretical and practical input which together creates a solution oriented process. The theoretical and practical approach is united through integrated design, which seeks to unite both architectural and engineering aspects. The problem solution is then found through a process of working with functional, aesthetics and technical characteristics (Knudstrup 2005). As mentioned the process in this project is based on the integrated design process. The design process unfolds itself in a very iterative process, which blurs the transitions between the different phases in the project. Traditionally the integrated design process is divided into five overall phases; problem, analysis, sketching, synthesis and presentation (Knudstrup 2005). It is of course very difficult to accurately divide the different phases in such a iterative process, where the road to solution I heavily influenced by Kolb’s learning cycle (Stice 1987). The process in designing a building is difficult to place in a specific box. It has certain elements as seen in the positivistic approach, as we know
it from traditional science (Bryman 2012). At the same time there are also strong relations to the hermeneutics, which is commonly used in social science (Bryman 2012). In the beginning of the project design process there has been a focus on understanding the site. This was done through a series of studies and mappings. These are all observing methods, and the use of them are mainly inductive. This means that there has been registered an amount of empirical data and from that created a theory (Bryman 2012). At the same time there have also been used a deductive approach, where existing theory have been processed and from that hypothesis’ have been made on empiricism. These two approaches are rarely completely distinguished from each other and is often combined the abductive method, which has also been used in the process (Bryman 2012). The process of acquiring new knowledge has to a high degree been through deductive literature studies. The literature used is made of both qualitative, thus often phenomenological, and quantitative registrations. The knowledge from these studies are based on registrations done by professional individuals and reinterpret, thus resulting in the use of double hermeneutics
(Bryman 2012). The idea-generating methods have mainly been visually oriented for example sketching, mockup models and 3D-modeling. The advantage in the visually oriented methods are their ability to communicate. Perhaps even more important, their ability to give rise to more ideas, by forcing the onlooker to relate to it and reflect upon it. This applies both for the analogue and digital tools in the process. The analogue approach has been dominating in the beginning, although they are very efficient later on when investigating a specific area. The process has been influenced by an early use of technical aspects which worked as knowledge in the further design development. This early exploration meant that the lessons learnt, could be used as a design parameter for the aesthetics rather than as a solution later on. Combined with an increased use of parametric tools allowing for a design method where changes to the design can be made later in the process, when for knowledge about the problem is greater. The parametric tools also allow for more and faster iterations than in a traditional approach.
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01
ANALYSIS
SITE
Introduction The project site is located on the Norwegian west coast, in Ålesund. Ålesund is among the 20 largest cities in the country and the municipality is almost twice as large as Kristiansund and Molde. Ålesund is Norway’s fishing capital where around 100 companies are taking part in the maritime industry. In 1904, a fire destroyed a large part of the city and the traditional Norwegian wooden house village disappeared. Quickly after the fire they started to rebuild the city, and after three years the city was rebuilt in a new style Art Nouveau. Never has that many Norwegian architects been so dedicated in such a big mission. Today the city is known as one of the finest Art Nouveau cities in Europe. (Ålesund Kommune 2015) The area for the site is close to the fjord with dynamic shores and islands. The site has various types of views of the mountains to the south and east of the fjord. It breathes the identity of the evergreen forest and the raw untreated nature, which allows multiple possibilities for the new church. The area used to belong to Spejlkavik parish, but because of a strong development in the east of Ålesund and because the population quickly increased, it was decided to divide the parish in to. The new church will therefore belong to Hatlehol parish. Hatlehol is the easternmost part in Ålesund and consist of about 8000 people. (Ålesund Kirkelige fellesråd 2008)
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ÅLESUND
Surroundings
Infrastructure
The site is 16.885 m2 and located centrally in the parish. A large cemetery is placed on the eastern side of the site. Not far from the site three suburban housing areas are located. Furthermore, the area consists of two factories, a sport complex, a public school and a car dealership. (Ă…KF 2008)
The site is located within good prospects for infrastructural opportunities. It is possible to arrive to the church by car from highway RV60, which is the main road between Ă…lesund and Bergen. RV60 runs by the northern border of the site. Furthermore, a bus stop is located on this road
close to the site. A bicycle and pedestrian path runs parallel to the road RV60 and connects the western and eastern part of the parish to the site. Along the site runs a small road that encircles it and connects the church to the parking spaces assisting the cemetery on the east. (Ă…KF 2008)
RV60 Busstop Housing area Site Housing area
Cemetery
Housing area
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Local nature The site is characterized by a very dense vegetation made up from various trees and bushes. The trees are not arranged in any way but are naturally spread throughout the terrain. The far majority of the trees are pines and secondarily there are also spruces. In addition to the coniferous trees there are a few foliiferous, more specifically birch trees along the creek, and
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occasionally an oak tree (Ă…KF 2008). Underneath the trees, and their dense crowns the terrain is characterized by wildly growing weeds mainly made up from heather and moss. The amount of the low vegetation makes the nature even more dense down at ground level (Ă…KF 2008).
Besides the vegetation on the site there are also multiple areas with exposed cliff, where the shallow earth and vegetation are penetrated by the bedrock beneath. This is especially happening around the places with the most concentrated shifts in elevation, and therefore often along the steep bank along the creek (Ă…KF 2008.)
Section The landscape within the site is as the rest of the area characterized by its steep terrain. The elevation of the site is highest at the northern end and slopes down towards the south. The total difference from one end to the other is 11 metes but with varying inclination. As shown on section south-north, ill. 1.5.
In addition to the dominating slope from south to north the site is also very undulating as the untouched naturally flowing terrain it is. As seen on the west-east section
Section cut south north
Section cut east west
Ill. 1.4 Section indicator
Elevation West-East
Ill. 1.5
Elevation South-North
Ill. 1.6
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Noise Generally the human ear perceives sound differently. Sound occurs in different octaves and the length of the sound waves changes in relation to the frequency. A noise study will therefore always be partly subjective, but with a use of sound receiving machines you can bring that to a minimum. (Aalborg University 2015) The primary noise source on the site comes from the traffic from the main road RV60. Furthermore, there are two football fields near by the site, which can course temporary noises. Besides the
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roads and football fields, the site is in an area with primary single-family houses. Because of the sites close proximity to the main roads there was in extension to the competition made a noise survey, in order to investigate exactly how much noise, the site was exposed to. The registrations were made on the road west of the plot, as marked on ill. 1.7, this means that it was made with none of the otherwise dense vegetation to shield from the noise. The results from the noise registrations came out with a maximum registration of 52.7 dB. Due to insecurities in the
measurements a factor of three dB is added with brings the overall result above what maximum allowed of 55 dB. Because the margin above the allowed limit is only 0.7 the noise report and the dense vegetation between the site and the road the engineers makes the assumption that the vegetation will shield the building enough when kept at the same distance to the roads as the registration were made e.g. 30 meters (Ă…KF 2008).
R V6 0 30 m
Sound receiver
R V6 0
Ill. 1.7 Diagram marking the noise effects on the site
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CLIMATE Sun
In Ă…lesund, Norway the length of the day varies significantly over the course of a year. During the summer solstice there is 20 hours of daylight, whilst
the hours of daylight during the shortest day of the year is less than five (Time and Date 2015). That is respectably two hours longer and 1.8 shorter
Summer Soltice
Winter Soltice
Summer Soltice
Winter Soltice
W
W
N
Altitude o 51
0
0
0
0
33
30
33
30
N Altitude o 4
24
0
30
24
0
30
21
0
60
21
0
60
S
Day Time 19:55
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0
0
Meridian 13:38
E 16
12
0
Rise 03:40
S
E 16
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than in Aalborg. The average amount of daily sun hours in a year is 9.48, disregarding clouds (World Weather and Climate Information 2015).
Set 23:36
Ill. 1.8
0
Rise Meridian Set 10:05 12:34 15:02 Day Time 4:57
Ill. 1.9
Precipitation The cloud cover in the area is quite dense with 18% clear skies. The median cloud cover in the area is mostly cloudy being at 87%, and doesn’t vary significantly over the year, ranging from 83% to 90%. In Aalborg the median cloud cover is 77% (WeatherSpark 2015). The probability of precipitation over the year is 64%, being most likely in January with 72% and least likely during may at 55%.
The temperatures in the region is relatively over a year taking its latitudinal position into account. The majority mean temperatures over a year varies within one and 16 degrees, and rarely below minus three degrees or above 20 degrees. The relatively steady temperatures are mainly due to the close proximity of the gulf stream (Yr. no 2015). The high temperatures also affect the amount of snowfall in the area makes up 20% of the annual precipitation, while it is 19% in Aalborg.
The most common form of precipitation is moderate rain which accounts for 54% of all the precipitation over the course of a year (Yr. no 2015). 20% of all the precipitation over a year is snow, and 39% during the cold seasons. In Aalborg the snowfall makes up 19% of the annual precipitation. The overall precipitation is 512mm and occurring 64% of the days annually (Yr.no 2015). For comparison the values for Aalborg is 767 mm and 63% (DMI 2015)
54%
19% 8%
3% Drizzle
12% 3%
1% Light rain
Moderate rain
Heavy rain
Light snow
Moderate snow
Thunderstorms
Ill. 1.10 Graph showing the annual precipitation
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THE CLIENT In the competition program there is some specific requirements and desires of the church function and architectural appearance. Therefore there is made a gathering of them all here to sum it up. Expectations from the town They ask for the church to be a place for the town to gather. A place which will give space for religious, cultural and social activities. They want the church to be the visual centerpiece of the city where the population can meet in sadness, joy, despair and hope. The churchwarden’s expectations The churchwarden expects the church to be a product of this time but at the same time for it to be traditional. It should combine past and future in a special way.
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The priest’s expectations The priest wants the church building to be the symbol on the meeting between humans and God. He thinks that the meeting between the individual human and God is personal and that the church should make this meeting possible. But at the same time he think that the church is for meeting God in community through the ceremonies, funerals, baptisms and more, so the church should also give the opportunity for this meeting. Overall desires In addition, there are requests for the church to: - Give identity to the town - Appear as a visual landmark in the landscape - Take the nature in consideration - Have fully functionality the rooms between
Functions in the church The competition program also contains a lot of requests for all the functions in the church. Such as where they should be, how big they should be and how they should be connected. On ill. 1.11 it is shown how the functions should be in the church and the connection the functions between. Outdoor functions In extension to the indoor functions there are also some requests for the outdoor functions such as an outdoor ceremonial place, a meditation path and a spot for outdoor photographing. The program can be found in appendix 1.
Room functions diagram Cloakroom
Music room
Refuse Office
Storage Activity room
Staff entrance
Mezzanine
Technical room
Storage
Additional sacritsty Sacristy
Church room
Children’s chaplel Congrega -tion hall
Chapel
Cloister room
Entrance hall
Sacred rooms Administration Common rooms Other rooms
Metting/dining
Sacristy for baptism
Workshop
Laundry room
Class room
Kitchen Church hall Near
Metting room
Connected Public toilet Staff toilet Ill. 1.11 Function diagram
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STUDIES Nordic architecture
“... The real Nordic architecture is to a degree shaped by the climate, the light (and its absence), the material resources and our sublime idea of the arctic latitude, that it constitutes its own regional construction” – Peter Mackeith (Hvattum 2012: 103) Nordic architecture can not be defined as one particular thing – it contains a lot of tendencies, but nevertheless a recurrent thing is the way to adapt to the place and take the context in consideration when designing. The naturalness, the honest use of materials, the tectonic clearness and the special ability to relate to the location, is some of the points highlighted when talking about Nordic architecture. (Hvattum 2012) But also nature metaphors, materiality
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and toning down the visuals to emphasize to the tactility in the architecture (Andersen & schelde 2012). Occorence - Briefly Nordic architecture, as we know it today, was first presented to the world at the Stockholm Exhibition in 1930 where the Swedish architect Gunnar Asplund showed his way of creating functionalistic architecture, which was influenced by the CIAM-movement and was a result of the time, and the elegance of the twenties classism. (Lund 2008) He also managed to combine the visually elegance with a strong social involvement, which became a distinctive element in Nordic architecture correlated with the Nordic tradition of welfare (Ibler 2014).
Ill. 1.12 Lofoten Tourist Road by JVA, invites to exploration and active participation and not the common consideration of a framed landscape – the postcard view.
The Scandinavian functionalism became light and sophisticated compared to usual European functionalism, and the softness of the architecture was only increased by the rationalistic usage of material and values that replaced the international style that reigned at the time (Lund 2008). Architects like Gunar Asplund, Jørn Utzon and Alvar Aalto were front figures of the foundation of the Nordic architecture – and wefts therefrom is still seen in the Nordic architecture today. Also Christian Norberg Shulz, Norwegian architect and theorist, has had a strong influence on the Nordic architectural thinking. He wrote a manifestation on behalf of the concept “Genius Loci”, a roman word for adaptation of architecture which captures the spirit of the place (Ibler 2014). The Genic Loci philosophy can be seen as a
Ill. 1.13 Lofoten Tourist Road by JVA
backlash to the international architecture style in the eighteens century (Andersen & Schelde 2012). According to Shulz’s, the architecture should be related to the spirit of the place and thereby the identity of the human. New nordic architecture tendencies The Nordic architecture is often applauded to be natural and authentic with a special feeling for the place where it is situated, but the tendency in new Nordic architecture moves towards a reinterpretation of the relation to the situated place in a wider consideration (Hvattum 2012). Where as the Nordic architecture is often said to grow out of the native soil, a new generation in Nordic architecture dissociates from the local nature and seeks into the horizon by creating
manmade contrasts to the nature rather than continuing it. Here meant that the architecture also can reflect the local history and cultural relic. Creating architecture in this matter, is a phenomenon that is a result of the resources and limitation of the site that creates new unexpected innovative solutions. An example of this phenomenon is Lofoten Tourist Road. The projects is a reinterpretation of how to create a tourist road project in Norway. Many other of these kind of projects use framing of the nature to give the tourists the postcardpicture of the nature as the main experience, but JVA chose another approach. They chose to buckle out bright yellow railing of scaffolding pipes along the rough terrain. The approach is at first glance not at all contextual, but actually the yellow colour
Ill. 1.14 In Oslo Opera by Snøhetta you are invited both into and on to the building, as the roof rises from the ground.
is a rendering of the most common bird on the area, the greater black-backed gull. The project invites to exploration and active participation and not the common consideration of a framed landscape – the postcard view. Instead of only locking at the landscape it is also an expiring of it – like walking the landscape. (Hvattum 2012). Another tendency in new Nordic architecture is the growing focus on the public solidarity and culture, which strongly can be seen in the capitals of the Scandinavian countries. The architecture is build to the population and is relating to the city and taking social sustainability into account. The strong involvement of the public life is not just a theoretical saying, but can be seen for instance in the opera of Oslo by Snøhetta or in Skuespilshuset in Copenhagen by Lundgaard
Ill. 1.15 Skuespilshuset in Copenhagen by Lungaard & Tranberg, where the public is invited in to the building by a natural route through the hall.
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Tranberg. These buildings live by the involvement of the public life, and this becomes their quality. What characterizes the new generation of Nordic architecture is, that it sticks deeper than a fundamentality concern in human needs and has ambitions, as a result of the consumption society, to the utopian vision of the society and to create architecture made by solidarity and with an authentic approach to the way we live as individuals and society, influenced by the growing welfare and the globalization tendencies. (MacKeith 2012). Partial conclusion The new Nordic architecture can in no way be generalized, and is under influence of many factors, and is taken many different directions. Many critics and theorists are involved in discussions on what characterizes Nordic architectures, and especially where it is going in the future. One of the fulcrums in the discussion on new Nordic architecture, is how it should reinterpret the traditional Nordic architecture. In this project the understanding and interpretation of Nordic architecture is going to be the work of making architecture in relation with the nature and sensing the spirit of the place.
History Materials
Geographic
Climate
Light (or its absence) Regional
Traditions
Welfare
Nordic Architecture
Social
Society
Culture
Tactility Tectonic clearness and honesty
Ill. 1.16 Diagram showing the aspects of Nordic architecture
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Church of Norway Before Christianity there had been no organized religion in Norway and The Church of Norway has for a thousand years represented the main expressions of religious belief in Norway. It has since the 16th century belonged to the Evangelical Lutheran branch of the Christian church and has since then been the state church until 2012. Today there is religious freedom in Norway, but the Evangelical Lutheran religious belief is still the country’s major religion. More than 75% of Norway’s population is currently a member of the Norwegian Church, but the
number is decreasing, and only three percent of the population is using the church regularly. (Church of Norway 2015). During the past several years, and particularly in the Middle Ages, there has been a widespread tradition of orientation of the churches. The churches should be facing east. Whether it has been obedience to a half thousand years old laws or uncritical respect for tradition is not known. Especially today there is a majority of modern churches, which are not facing east. One of the
main reasons is, that in order to accommodate the functions in the churches, they had to compromise and give more consideration to street layouts or functionality than corners of the world. The function of the church is therefor more important, however, it may be an advantage to make the churches facing east in the high and often dark North, as it will certainly give a great symbolic value by allowing the church receive sunlight through an east window behind the altar. (Moderne Dansk Kirkearkitektur 2015)
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Norwegian architecture Norway have always had a strong tradition for using wood in the construction of buildings. Historically it has by far been the dominating material, while stone was a lengthier and more expensive process to use. (Norway Connects 2012). Therefore, stone as a material was used mainly to construct castles later churches. The traditional usage of wood in Norway was characterized by two approaches to the traditional types of building methods. The first one being
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cog-jointed log houses, originating from the vast forests in the forest belt in the eastern part of Norway. The second is the stave construction method with its origins in the rugged and forded western part of Norway. In the western parts of the country the wood is sparser, and called for a more economical way of building (Titelius 2013). The solution was the stave system that relies on a structural system of fewer large loadbearing elements in the form of posts or staves. This structural system was then cladded with smaller
wooden elements with not structural purpose, panels for the walls and shingles for the roof to create the envelope (Hipple 2015). Of cause fusions between both typologies have occurred mainly in the central parts of the country. As mentioned earlier the stone was not the most widely used material, however when the AngloSaxons missionaries brought with them the masonry technique. This boosted the use of stone in Norwegian architecture. In the period from
1350 to 1450 the development in construction ceased, mainly because of the black death. In the 16th century, when the Danes invaded Norway the progress started again (Malmquist 2013). The nest big step in Norwegian architecture came in the 19th century, the Swiss style emerged and introduced new way of working with technologies and especially the details. The context in the Alps fitted well within the Norwegian context, and the Norwegians embraced it and created their
own style. This is what is generally recognized as the Norwegian style (Seip 2015). When the modernism was dominating during the 20th century a group of Norwegian architects started in the 80’s to abandon the excessive use of concrete, and return to the traditional material wood. The way wood was brought into the 21st century was through the use of modern technologies in the production and treatment.
wooden architecture begun. In 2010 the Norwegian authorities introduced the Norwegian architecture policy, called architecture.now. This document provides guidelines to how new buildings should take into consideration (Almaas 2010). Generally focus is on the how the architecture relates to the site, how it uses the local materials and how the building relates to the community (Kultur- og kirkedepartementet 2009).
At this point the era of Norwegian contemporary
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Tectonic The word tectonic is descended from the Greek word ‘tekton’, which means carpenter or builder. Also remnants of the term can be found in literature and poetry of the ancient times. For instance, Homer, where the usage of the term refers to the general art of construction. The role of the tekton undergoes evolution through the ancient time, and eventually it evolved to the emergence of the master builder called the architekton. (Frampton 1995) “Tectonic becomes the art of joinings.’’ “Art” here is to be understood as encompassing tekne, and therefore indicates tectonic as assemblage not only of the building parts but also of objects, indeed of artwork in a narrower sense. Gottfried Semper published Four Elements of Architecture in 1851, where he divides the primordial dwelling into four basic elements; rampart, hearth, the roof and walls - some creating enclosure and a shelter, and tectonics of creating spatial constructions and atmosphere. From here he categorized the building crafts into two fundamental procedures – the tectonics of the frame, and the stereotomics of the rampart – which can be seen in the way that the light framework rises from the mass of the foundation. Frampton declared that construction
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and structure in space is not only about the constructive technology, but about its expressive potential. For him the tectonics should be a poetic combination of construction, that in the whole picture creates surfaces and volumes and therefore spaces (Frampton 1995). The structural engineer Dan Engström argues that amongst architects the word tectonic has become a fashion to use and has become indistinct. Today many use it to describe architecture that uncritically shows the load bearing construction. To him tectonic architecture uses e.g. bearing and structural elements, to create experiences (Engström 2004) Space has become a part of the architectural thinking. Martin Heidegager broach following in this essay of 1954 entitled “Building, Dwelling, Thinking’’: “(…) Raum (red. room) means a place cleared or freed for settlement and lodging. A space is something that has been made room for, something that is cleared or freed for settlement and lodging. A space is something that has been made room for, something that is cleared and free, namely within a boundary, Greek peras. A boundary is not that at which something stops, but, as the Greeks recognized, the boundary is that from which something begins its presenting.” This seeks to understand the way, that space
should be thought about in a tectonic matter. Also Steen Eiler Rasmussen thinks of the tectonic of space, and in his book “Experiencing Architecture of 1959, he describes the theory of ‘hearing architecture’, where he emphasizes the importance of the acoustical character of the architecture which will effect the spatial reflection or absorption of sound which have impact on the psychological response to the understanding of the room. Today almost every project it digitized and projects are designed using computational tools starting in increasingly earlier stages in the design phase. These tools open new doors structurally and therefore architecturally. In extension to this, these new tools also promotes closer and earlier collaborations between architects and engineers. This has also resulted in a renewed and growing interest for design using structural principles. (Nilsson 2007) The new digital tools combined changes in the industrial production, which has now become digitally directed, the production is no longer depending on a series of repetitive identical products. We are in an age mass production there will soon be obsolete and moving on to mass customization. Newly produced elements are unique and can therefore be optimized
individually to its constructive purposes. (Kieran & Timberlake 2004) The Nordic tectonics can be seen rather simple, with an authenticity and honest approach of materials. Often no decorative elements and plasters are used, but the architecture appears light, simple and pure. Often the detail in the craft methods used for Nordic architecture can relate to the regional. All of this can though be argued in many large contemporary buildings, where the honesty of material is cut and the craft methods are more industrializes and globalized than regional. Tectonics seems to be a very broad expression, and has perhaps been used to much and indistinctly. Trough new digital tools it has become easier for the “massesâ€? to use it earlier and earlier in the design phase. But this could according to EngstrĂśm also mean that the architect should be even more delicate and critical in what way to show the structural elements in a building. It is without a doubt one of not the most central parts in construction, and its importance in creating spaces can hardly be underestimated. With the ability to do greatly complicated structures the architect would also have a responsibility not to carried away.
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Acoustic In his book experiencing architecture Steen Eiler Rasmussen discusses if architecture can be heard. He implies that because architecture reflects sound the same way as light, it can be heard just as it can be seen (Rasmussen 1964). This really emphasise the importance of the acoustical properties in a room. How a room behaves acoustically can completely change the users perception of the room (Rasmussen 1964) When designing a church one of the most important parameters for the design process is the acoustical properties of the church room. A
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church room is acoustically rather complex, as it should accommodate both a long reverberation time for the music in the room while it also needs to support intelligible speech (Egan 2007). The acoustical characteristics of a room is highly depended on the shape of the room, whether the materials are reflective or absorbent. So all in all the volume shape finishing will affect the articulation of speech and the quality of music (Egan 2007) One of the key parameters to evaluate when designing a place for worship, is the reverberation time. The reverberation time is an indicator for
how long time the sound energy lasts. Normally churches should have a reverberation time above 1.4 seconds, in order to create the right sense of intimacy (Egan 2007). If it’s also used for organ music the reverberation time is recommended to be between 2 and 2.4 seconds (Egan 2007). Another aspect to keep in mind is the clarity in the room, it is and expression for the relation between early to late sound energy ratio. If the clarity is below 0 dB it means that the late energy is dominating. The higher the value is the more the initial sound dominates, making the
sound seem more clear. According to the British standard in measurement of room acoustics, it is recommended to have a clarity between -2 and 2 dB (British Standard Group 2009). The definition of a room is an expression of the early to total sound energy ratio. The closer the value is to one the higher is the definition of speech. Acceptable values for the definition in a church is between 0.3 and 0.7 (Cunha & Smiderle & Bertoli 2013). It is really a balance between creating a room with a long reverberation time favourable for the music and having a room
with a clear definition favoured for speech. When designing a church room one can use different guidelines to achieve good acoustical conditions. The volume of the room is important. It is advised to have 5.5 to 8.5 cubic metres per person. The number of churchgoers as they are the most effective absorbents in the church, therefore they should also be taken into account. Reflectors such as a canopies as seen above the pulpit in old catholic churches can be used to direct sound. Avoidance of domes, barrel vaults and other concave shapes (Cavanaugh 1959).
1x
500 x
0.7 m2
350 m2 Ill. 1.17 Person to area ratio
1x
500 x
5.7 -> 11.3 m3
2850 -> 5650 m3
Ill. 1.18 Person to volume ratio
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SUMMARY OF ANALYSIS The new church will be located in the parish of Hatlehol in the eastern part of Ă…lesund, Norway. The site is surrounded by various functions, of which, the most important is the cemetery. The site is easy assessable by different forms of transport from the main road RV60 north of the site. Furthermore some smaller roads runs along the site and encircles it but are not crucial. The site is an undulating landscape, sloping from the north to the south containing wild nature with dense vegetation. In this part of Norway the length of the day varies significantly over the course of the year and with less than five hours
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of daylight on the shortest day, the site will have a general lack of daylight during the winter. The keyword in Nordic architecture is the naturalness, the honest use of material, the tectonic clearness and the special ability to relate to the location. Nordic can be considered as an awareness and respect of the context through use of local material and an understanding of the local conditions and landscape. This is also the reason why the traditional building material in Norway is timber, chosen for its local availability and practicality.
Tectonics seems to be a very broad expression but can be considered as use of structure, construction, materials and detailing to improve desired atmospheres and appeal to human senses through view, light, acoustics and tactility. The Nordic tectonics can be seen rather simple, with an authenticity and honest approach of materials. Often no decorative elements and plasters are used, but the architecture appears light, simple and pure. Often the detail in the craft methods used for Nordic architecture can relate to the regional.
VISION
The vision of the project is to design a church that will give identity to the town in form of a visual landmark, to create a sacred environment, inside and outside, through light, materials and architectural form. And in all this, to create a flow in the building, there accommodate the client’s need.
DESIGN CRITERIA
-Create a new landmark for the local community around Hatlehol -Respect the nature and use the natural terrain on the site -Create the frame for a spiritually strong experience for the users -Use the exterior space to create an experience for the visitor, and use it to frame the architecture and the nature -The architecture should represent the values in Nordic architecture -Unify the spiritual functions with the regular usage of the churches other facilities -Respect the requests and needs to the functions and connections in the program from the client
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02
PRESENTATION
DESIGN CONCEPT The church is placed on the northern part of the site, where the elevation is on its highest, and by that the sloping form can complete the elevation like the top of a mountain. Based on the Nordic traditions of complimenting the landscape and the nature, most of the church is placed under
The church is placed on top of the building
Complex dug down
34
the ground. Only the most important part of the church, the church room, is seen above the ground. The form of the church room is extremely clean and elegant and is sloping towards the sky. On this location the church will also have the mountains in the background. The
rest of the building, there is under the ground, is lit up by five big courtyards there is cut down trough the earth to the building. The courtyards give a lot of light to the building, but even more important it brings the nature into the building.
The church continue the terrain towards the sky
Additional functions is layed out besides the church
Openings created for light and access
Bringing nature into the building
Ill. 2.1 Design concept
MASTER PLAN
N 25[m]
Ill. 2.2 For 1:500 plan see drawing no. 10
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PLAN
1 Church room – 763 m2 2 Sacristy for baptism – 42 m2 3 Toilet – 37 m2 4 Meeting room – 39 m2 5 Staff toilet – 10 m2 6 Office – 137 m2
7 Additional sacristy – 23 m2 8 Sacristy – 14 m2 9 Storage – 31 m2 10 Entrance Hall – 580 m2 11 Storage – 38 m2 12 Congregation hall – 153 m2
13 Kitchen – 59 m2 14 Disp. – 16 m2 15 Cloister – 16 m2 16 Chapel – 100 m2 17 Technical room – 37 m2 18 Church hall – 92 m2
19 Children’s chapel – 53 m2 20 Class room – 23 m2 21 Class room – 24 m2 22 Toilet – 23 m2 23 Activity room – 43 m2 24 Workshop – 29 m2 25 Music room – 29 m2 26 Refuse – 13 m2
16 11
14 15
13
8
17 1 12
9
19
7
2 3
22 10
20
18
23
24
4 21 25 6 5
26
N
36
Ill. 2.3 For 1:200 plan see drawing no. 9. For evacuation plan see appendix 2.
SECTIONS
Ill. 2.4 For 1:200 section see drawing no. 3
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Ill. 2.5 For 1:100 section see drawing no. 4
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Ill. 2.6 For 1:200 section see drawing no. 2
39
40
Ill. 2.7 For 1:200 section see drawing no. 1
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ELEVATION
Elevation north Ill. 2.8 For 1:200 elevation see drawing no. 5
Elevation south Ill. 2.9 For 1:200 elevation see drawing no. 6
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Elevation east Ill. 2.10 For 1:200 elevation see drawing no. 7
Elevation west Ill. 2.11 For 1:200 elevation see drawing no. 8
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Concrete walls Wooden walls Concrete/Wood walls Glass walls
MATERIALS Honesty is an important part of this project, which is reflected in the materials chosen. All the outer walls are constructed in grey concrete, showing their structural purpose for the load from the earth. Furthermore the concrete reflects the light, which is appreciated in these dark areas. All the floors
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Ill. 2.13 Grey concrete
Ill. 2.12 Plan showing the materials used in different elements in the building
in the church are also made of grey concrete. From the outside the only visible material on the church is pinewood. The pinewood is treated with iron sulfate, which protects the wood against the weather and gives the wood a silver-gray color
Ill. 2.14 Iron sulfate treated pine
through time (Norsk Treteknisk Institutt 2012). For further information on iron sulfate see appendix 3. On the inner walls the material is untreated pinewood. Entrances and all courtyards are made in glass in order to get as much light in as possible.
Ill. 2.15 Normal untreated pine.
OUTDOOR To respond the clients requests of outdoor areas, there has been created several paths around the site with different purposes. The paths are divided into three different categories; a creek path, an architectural path and a forest path. These three paths have got three different focus points. The creek path travels along the water on the western part of the site. The architectural path moves on top of the building and leads the visitor to see both the church tower and the courtyards, which creates a visibility inside the building. The last path, the forest path, is placed on the eastern side of the site and is thought to have very dense and wild nature surrounding it. Furthermore, there is a main path, which connects the entrances with the parking lot. This path is also connected to a service road. Enabling access for special vehicles such as ambulances, hearses, disabled transportation and for fire engines to come with the required distance of the building. The two main paths culminate in front of the entrances, which creates a church square. The tree meditative paths are connected to the main paths and besides that they meet up and are connected north of the church tower. Here the path system is also connected to the main road allowing for access for the visitor using public transport. The ceremonial place is positioned as a part of the steep terrain on the eastern part of the site, and is connected to both the church
square and the forest path. The ceremonial place and the area north of the church are
both located in order to provide a photographic scenery, framing both architecture and nature.
Ill. 2.16 Diagram showing outdoor area
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VISUALIZATIONS
Creek path
Different paths are situated in the surrounding landscape of the church. In this case, the meeting between the church tower when walking on the creek path is shown. At this angle the church tower shows its both strict and sloping surface, that almost stands out as a mountain in the landscape. Because of the horizontal window ribbon, the tower will also light up as a landmark during the night time.
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Ill. 2.17
Entrance
When arriving to the front of the church, you are met by entrances cut into the terrain, which leads into the building. These two entrances are the only part, aside from the church tower, that is visible on the site. From this angle, the shape of the church tower is really shown to it’s full advantage - the sharp tip pointing towards the sky. Also this angle reveals the meeting between the building and the landscape, and shows how the building is cut into the terrain. Ill. 2.18
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Church room
The main church room is dominated by light interior together with the brightness of the diffuse northern light. The concrete is used in the lower part of the walls and on the floor, which is under the ground, in relation to the honesty in material usage. The dominance of the roof slope gives a majestic feeling and creates a sacred feeling.
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Ill. 2.19
Chapel
The chapel has a mysterious feeling, with a more intimate experience compared to the main church room. The appurtenant courtyard is emphasizing a calm and artless experience by the usage of water, bedrock stone and light and it’s absence. The dominant usage of concrete, together with the bedrock on the outside, gives the chapel a rough tactility. Ill. 2.20
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View to the chapel
Already when entering the building, the glance is drawn towards the chapel. It stands out as a separate part, with a whole other purpose than any other functions. However, it still becomes a part of the entire experience of the building in the way, that the journey towards the chapel both includes the transparency to other rooms and the greenery in the court yard. Both light and warmth, and cold and rough materials meets in this part of the building, which makes it a unique place.
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Ill. 2.21
Courtyard
To get enough light into the building, several courtyards are made. These provides light for the rooms that requires daylight. Furthermore, the court yards draw the green element into the building, and creates a strong relation to the nature. The courtyards should be usable for the visitors and to emphasize that, the relation from the inside and out is made in an attempting of blurring the boundary. Ill. 2.22
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Outdoor area
This render shows the approach to the church from the north eastern part of the site. Here you are meet by the dominant pointy, but yet elegant roof of the church, which is the only part visible above ground. The view, that you are meet with in this particular sight, really clarify the vision of the building – a clear shape grown out of the terrain, standing out as a landmark and growing out of the landscape and melt into the nature. This shows the creating of a new landmark in Hatlehol. Ill. 2.23
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STRUCTUAL Church room
The structural system in the main church room is based on a wooden structure. The bottom part of the structure are composed of two parts. The exterior walls towards the terrain are concrete walls, and the back wall in the room is based on eight wooden pillars, one for each beam above. The exterior wall above the terrain is made from a frame construction. The frame is applying shear wall effect to the structure enabling it to withstand the horizontal forces inflicted on it. Attached to the top point in the frame construction and on each pillar in the back wall is the curved beams. The curved beams are giving the roof its overall shape. The section of the members varies throughout the beams to optimize the use of material making the cross section as small as possible to accommodate both efficiency, the joining at the top and the bending forces within. The last elements are the top beams running between the curved beams, and supports the roof. The curved beams are divided into two sizes according to the loads applied to them, which varies especially due to the varying snow load. For further results see appendix 4.
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Top Beams
Curved Beams
Front Wall Elements Back Wall Pillars
Concrete Walls
700x500 500x400
260x150
83% 84%
93%
350x200 500x300
660x420
94% 590x400
450x450
95%
97%
99% 98%
400x400
75% Ill. 2.24 The church room’s structual system
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The rest of the building Besides the church room, there is also developed a structural system for the rest of the church complex. Due to the fact that the main part of the building is dug down under ground, the exterior walls are constructed in reinforced concrete. This means that the exterior walls are loadbearing elements transferring the vertical loads down to the ground. The rest of the structure is made in wood. The roof is supported by a series horizontal beam elements, in three different section dimensions. The horizontal beams transfer the loads to the pillars that transfers the loads down to the ground. The pillars are placed as a part of the interior walls. The restraints for the system is fixed connections for the bottom end of the pillars and hinged connections on top of the exterior walls supporting some of the beams. More details on the results and process can be found in Appendix 5.
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Tetiary Beams
Secondary Beams
Primary Beams
Pillars
Concrete Walls
Congregation Hall Pillars
280x140
440x220
650x350
350x350
550x550
Ill. 2.25 Structual system of the rest of the building
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DETAILS From a structural point of view there is a need for diving further down to the details of the building to get an understanding of how the structure works and how it should be build. The details are made in specific places in the building and are showing what materials is used and how the materials are connected. There is a total
58
of seven different details for this project, which show the most critical places for this structure, such as the top point in the church room and several details of courtyard issues. The next pages shows the most important details and rest of the details can be found in appendix 6.
Cross section CALE :50 20 3 1 12 2-5 65 1 50 -
Green estate Green roof substrate Filter layer Drainage layer Protection mat Waterproof membrane PIR insulation Vapour control layer Light conrete - 2% slope layer Wooden slab HPL layer Airspace for installations Suspended wooden panels
Detail A
+460 1 Story
300
50
110
+460 1 Story
Âą0 0 Ground Floor
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Âą0 0 Ground Floor
5 12 20 5 30
Concrete Protection layer PIR insulation Rainforced concrete slab Waterproof membrane Flatting light conrete layer Lime sand
Detail B
Ill. 2.26 Cross section
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Detail A - 1:20
A
1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11.
1. Glass railing (2 layers) 2. Zinc L-shape profile with protection mat from railing side 3. 30x150mm wooden panels 4. L-shape steel profile mounted with screws 5. Steel add-ons for the rail’s bolts 6. 30x70mm timber vertical cladding element 7. 300x650mm timber beam
 8. Railing steel bolts 9. 120mm of PIR thermal insulation 10. 30x70mm timber horizontal cladding element 11. 30x300mm suspended wooden panels 12. Vertical steel support elements for the curtain wall 13. 80x150mm curtain wall aluminum system 14. Electric cable trace 15. Suspended ceiling twig
12. 13.
15. 14.
Detail A 60
Ill. 2.27 Detail A 1:20
Detail B - 1:20
B
1.
8.
7. 6.
Detail B
2. 3. 4. 5.
1. Curtain wall (3 layers of glazing) 2. External additional silicon gum 3. 80x150mm curtain wall aluminium system 4. 5mm protection layer 5. 120mm of PIR thermal insulation 6. Protection layer 7. Internal additional silicon gum 8. Floor heating in concrete layer
Ill. 2.28 Detail B 1:20
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Detail C - 1:20 C
3. 2.
1.
4. 5. 6. 7.
8.
W1
Detail C 62
W1 30 Wooden panels 30 Horizontal support element of the cladding 150 Wool insulation 50 Acoustic styrofoam 150 Wool insulation 30 Horizontal support element of the cladding 30 Wooden panels 1. 80x150mm curtain wall aluminium system 2. 80mm of PIR thermal insulation 3. 50mm of PIR thermal insulation 4. L-shape wooden panels 5. 30mm of PIR thermal insulation 6. 350x350mm timber pillar 7. 100x350mm timber vertical support for the internal cladding 8. 30x50mm timber horizontal support element of the cladding
Ill. 2.29 Detail C 1:20
D
Detail D - 1:20
1. 2.
CRW1
CRW1 30 Wooden panels 30 Horizontal support elements of the cladding 30 Vertical support elements - Windproof membrane 50 PIR thermal insulation 150 Wool insulation 100 Acoustic insulation 150 Wool insulation - Vapor proof membrane 30 Horizontal support elements of the cladding 30 Wooden panels 1. 100x400mm timber vertical support for the internal cladding 2. 400x400mm timber pillar
Detail D
Ill. 5.10 Detail D 1:20
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Detail G - 1:50 CRR1 30 Wooden panels 100 Support element for the panels (direction with the slope of the surface) 300 Curved wooden beam - Vapor proof membrane 200 PIR thermal insulation - Waterproof membrane 50 Support element for the panels (direction with the slope of the surface) 50 Exterior wooden panels CRR2 200 Wooden support element for the insulation layer 200 PIR thermal insulation - Waterproof membrane 5 Support element for the panels (direction with the slope of the surface) 5 Exterior wooden panels CW2 200 PIR thermal insulation - Windproof membrane 30 Vertical support elements 30 Horizontal support elements of the cladding 30 Wooden panels 1. Air space 2. Light steel truss 3. From this height above support elements for the elevation should be connected directly to the steel truss
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4. Wooden beam with steel cross profile inside - support for the light truss finish of the “toping” 5. Steel cap (“toping”) with the triangular elements for the bolt connection with the beams 6. Steel bolts connecting the cap with wooden beam inside 7. Wooden beam (screwed to the steel profile) 8. Steel profile 9. Steel bolt 10. Beam’s steel element with two rounded profiles (for bolt connection to the toping) 11. Steel wires for suspended horizontal wooden supports 12. Steel bolts 13. Wooden beam - support for the insulation and support elements for the wooden elevation 14. [inside the beam] Steel profile connected to the beam with steel bolts 15. Wooden supports for the cladding 16. Wooden panels screwed to horizontal supporting element 17. Wooden panels screwed to the beam 18. Wooden supporting beam 19. Aluminum profile for church glazing 20. Horizontal wooden panels 21. Horizontal support elements for the horizontal panels
+ 35,00
SCALE 1:20
1.
G
Structure scheme Structure scheme 2.
3.
4.
5. 6.
CRW2
CRR2
7. 8. 9. 10.
11. 12. 13.
21. 20.
14.
19. 18. 17.
CRR1
16. 15.
Detail G
Ill. 2.31 Detail G 1:50
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ACOUSTIC The requirements in the competition material presented a need for a church room suitable for both music and speech. The church room is designed to have the organ and the choir in the front of the audience, to make it not only an auditory but also a visual experience. The organ is placed to the right front and the choir to the left of the audience. Furthermore,
Priest
the priest is positioned centrally all the way in the front of the room. The idea behind the positioning of the priest, organ and choir, was to differentiate the reverberation time. The purpose of this was be to have a high reverberation time for the music and shorter for the priest. However, it was not as successful as hoped for.
There are used no acoustic panels in the final design for the church room it relies only on the main materials of the room and its overall geometry. The concrete in the bottom of the room is the most effective reflector, and the convex shaped ceiling functions as one big diffuser scattering the reflection throughout the room.
Organ Back receiver
Choir Ill. 2.34 Record of original music
Ill. 2.32 Record of original speech
Front receiver
Ill. 2.35 Music from organ position recorded by the front receiver
Ill. 2.33 Speech from priest position recorded by the front receiver
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Ill. 2.36
The final acoustical results for the church room, is as showed in the graphs below. The reverberation time should between 2.0 – 2.5 seconds to accommodate a good environment for music. The reverberation time is in the fully occupied church room just below for both the organ and the priest. When the room is half full the reverberation time is right in the middle of the optimal span.
The clarity in the room is in generally very good as well with almost all the cases falling between the preferred span of negative two to two. The same goes for the definition where the far majority of the results are above the minimum. It is really a balance between the many factors when designing an acoustically multifunctional
T30 Priest [s]
2,7
room. If the definition for example would be raised, the clarity increases and the reverberation decreases and moves out of their optimal zones. In extension to this the room should also function with different amounts of people, which makes the window of successful results even smaller.
T30 Organ [s]
2,7
2,5
2,5
Half-‐Priest to Front
2,3
Half-‐Organ to Front
2,3
Full-‐Priest to Front 2,1
Half-‐Priest to Back Full-‐Priest to Back
1,9
Full-‐Organ to Front 2,1
Half-‐Organ to Back Full-‐Organ to Back
1,9
min 1,7 1,5
max
62,5
125
250
500
1000
2000
4000
1,5
8000
C80 Priest [dB]
4
min 1,7
3
3 2
1
Half-‐Priest to Front
0
Full-‐Priest to Front Half-‐Priest to Back
-‐1
Full-‐Priest to Back
-‐2
min
-‐3
max
-‐4 62,5
125
250
500
1000
125
250
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2000
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C80 Organ [dB]
1
Half-‐Organ to Front
0
Full-‐Organ to Front Half-‐Organ to Back
-‐1
Full-‐Organ to Back
-‐2
min
-‐3
max
-‐4 -‐5
62,5
125
250
500
1000
2000
4000
8000
Ill. 2.37 Acoustical results
D50 [%]
50
62,5
4
2
-‐5
max
45 40 35
Half-‐Priest to Front
30 25
Full-‐Priest to Front
20
Half-‐Priest to Back
15
Full-‐Priest to Back
10
min
5 0
62,5
125
250
500
1000
2000
4000
8000
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03
DESIGN PROCESS
INTRODUCTION The design process for the project is based on the analysis’ and theories’. There has been an extensive focus on using performance aided design as a part of the integrated design process. The process is in this section divided and presented in six separate phases describing the main elements in the final project. Each separately presented segment of the process, consists of everything from the early
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sketches and models to the final optimisation and detailing. Of cause the different segments presented here is in reality very difficult to define individually and are overlapping in the process of making the project as a whole. The overall process has right from the beginning been heavily influenced by input from the acoustical, and not much later, the structural performance of the building. This has resulted in a
process were the overall designing of the building has had a lot of input from very quantitative and measurable studies besides the aesthetics. It is very important to stress the fact that the actual design process was not this divided nor linear. This has been done purely to break it down into separate parts in an attempt to present it in a more understandable manner.
Design process diagram Workshop 1 - Acoustics
Workshop 2 - Structure
Acoustics
Structure
Church room
Plan
Light
Courtyard
Chapel Ill. 3.1 Design process
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ACOUSTICS Phase 1
The overall process started with a workshop in acoustics. The focus with the workshop was on exploring different geometries from an acoustical point of view, and explore what effect different geometries had on acoustical performance of a room. In the beginning the shapes were drastically different and represented various examples of overall shapes cubic, prismatic, curved etc. This
was mainly done to get an understanding on how geometry of a room affected its acoustical performance. In extension to the general acoustical analysis, two types of roofs dominated the further process - the jagged roof and the convex shape, which both have an excellent ability to scatter the sound in order not to create echo.
Ill. 3.2 The results were evaluated from a comparison of the different model in charts. The charts were made so the required area for both clarity and reverberation was highlighted, as it’s seen above.
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Phase 2 The next phase was to take the concepts that worked the best and go into more detail with those, by for example introducing multiple sources and receivers for sound and experimenting with different materials. In order to make the comparisons as accurate as possible it was important to set up the parameters of each phase prior to the experimentation. For example, it was important to keep the volume
and materials of the rooms consistent as it has a big effect on the reverberation time. This could then give an unclear image of the results and make comparisons harder. After each phase it was found important to thoroughly sum up and evaluate the results, and least but not last conclude on what would be the next step to explore. At the end of the intense workshop it was found
very important to evaluate the results graphically in order to get an overview of the results. This was because of the immense amount of data to process, if there were to many uncertainties when trying to compare the actual number instead of having them as a graph. The result of this workshop can be seen on the following pages.
Ill. 3.3 The pictures above shows some of the models that evolved from the first acoustical phase. The models show how different shapes were used in order to clarify how the idioms affected the acoustic.
Ill.3.4 Again, the results were evaluated from a comparison of the different model in charts. The models were evaluated in multiple cases taking the different positions of the audience in consideration. This was mainly done to examine how the placing of the organ and priest made most sense in acoustical regard.
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Subsequent work For the design the workshop had a huge effect on the later work, thanks to this it was possible to very quickly decide on what overall shape should be carried on the later work. This also allowed the normally lengthy initial sketching phase to be shorted significantly as the frame for the overall image was already set. The later work with the acoustics of the church room moved on to a way more detailed level. In the beginning it was a big factor in deciding
on the materials in the church room, as it could be used as a very clear quantitative factor. Parallel to the structural development there was made numerous iterations through parametric modelling. These iterations focused on very small changes in the overall geometry of the room, in everything from the height of the individual pillars altering the height in certain parts of the room, to small changes in the curvature of the roof. Also slight changes in the positioning of the priest,
choir and audience could quickly be evaluated and used as a deciding factor for the interior of the church room. The tools mainly used has been computational modelling tools for modelling everything from the simple start geometries to the parametric and more complex final geometries. The calculations and auralizations was done using computational tools as well. But also simple hand sketching was used in the very beginning of the process.
Ill.3.5 The model seen above was an iteration from phase 2 in the acoustical workshop. This was the form, that caught on the further acoustical process. The shape of dramatic up going roof was also found interesting in aesthetical and structural aspects. This model laid out the foundation for the further work on the church room. Therefore, this model was undergoing further iterations in the program Pachyderm, and several parameters were changed during the process in order to create the optimal acoustics for the church room.
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Ill. 3.6 Above some examples of acoustical iterations of the church room. Parameters of the roof shape was changed in order to find to optimal acoustic, required for the church. The charts were used in order to compare the results.
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STRUCTURAL Workshop introduction
concave shapes could be to the acoustic performance. Traditional compressive structures work very well structurally in a concave shape. With this as a starting point the workshop was used to explore different structural systems to find a solution to how the structural system could
Solution
Problem
In extension to the acoustics workshop held in the beginning of the project, a second workshop on the structure of the church room followed. One of the main lessons learned from the acoustic workshop was how effective convex shapes worked, not to mention how problematic
Ill. 3.7 Above the initial concerns brought from the acoustical part till the structural part is illustrated.
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also accommodate the acoustic goals, while still having an aesthetically strong shape.
Phase 1 The first phase of the workshop was much like the acoustic workshop, focused on very different systems. The goal of this was to try many different systems and explore their potential. Of cause the convex shape was a broad hint to use a tensile structure. Again in this workshop it was
important to have the results as comparable as possible, so defining a frame for the experiments was extremely important e.g. having the same height and span. In order to keep it as simple as possible the very first phase was made as a one dimensional structure. These structures
where then tested with exploratory loads, and evaluated. For this part the structures modelled using parametric software, and tested with simple vertical loads. The results can be seen on the following illustrations.
PHASE 1 PHASE - INVESTIGATING THE CONVEX SHAPE SHAPE 1 - INVESTIGATING THE CONVEX Width of the module: 20 m
Load applied: 1000 kN Load applied: 1000 kN Section dimensions of the elements: 12x24 cm Section dimensions of the elements: 12x24 cm
Concept T1
Statically indeterminated
Deformations, momentums,momentums, tensions, compressions Deformations, tensions, compressions T3
C1
T1
Concept T3 Statically determinated
T1
Concept T2
Statically indeterminated
2250 1500
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•
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C1 • •
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Elevation
400 200
Elevation Perspective view
• Perspective view •
0
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C2
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ty for collapse due to robustness ty for collapse due to robustness • Pillars Pillars
T3
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Max. compressions
T2
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T2 T3 T2 T3 0 0 T2 T3 C1 C3 T3 C1 C2 T3 C1 C3 T2 T1 T2 LowT1Displacement • LowT1Displacement • C2 T2No pillars • No pillars • C2 T1 No pillars • Simple design • Simple • design Sloped roof • roof Simple construction • Sloped • Sloped roof • Sloped roof • Covered convex shape • convex Sloped roof • Covered shape • Few parts means larger • possibiliFew parts means larger possibili• • High displacement T1
T3
375 250
T3
1,24
T1
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C1 C2 No pillars Simple construction Sloped roof High displacement
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C1 C2 C3 C2 C3 • Visible shapehave a sloped • Doesn’t a sloped roof roof • Have a sloped roof Visible convex shape • convex Doesn’t roof • haveHave a sloped • lower Larger of visibly part lower • Partly•visiblyVisibly structure • Visibly convex shape Larger amount of part • amount Partly structure convex shape • High maximum tension and possibility for collapse possibility for collapse • High maximum tension and • More material compression More material compression top • roof Doesn’t have a sloped roof Have a Doesn’t have a sloped • Have a top •
Ill. 3.8 The purpose of the second phase in the structural workshop was with the agenda to investigate the convex shape working in mainly tension or compression. Above the scheme of results form the phase is shown. The comparison was done with charts together with a qualitative evaluation.
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Phase 2 For the second part of the workshop the focus moved on to exploring how the different structural concepts from the first phase could be implemented into a spatial system, and accommodate a room within. Here the majorities
of the systems were structures that were either truss’ or working mainly in tension. So of cause a lot of the focus were on how a tensional system could be pinned in a high node and still keeping a functional interior and the aesthetics in mind.
Here simple physical working models was the main media accompanied by computational calculations. Also researching on other cases that had similar challenges proved a great help.
Ill. 3.9 Here the physical models from phase two are shown together with some perspectives of the volume, that is created by the structure.
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Phase 3 The next part of the workshop went from being exploratory with many structural concepts to be more about the iterations of the once who performed the best in the previous phases.
The loads for the calculations were now done with partial coefficients and load combination factors in accordance to Eurocode with both ultimate and service limit state. This resulted in
a temporary structural system relying on truss as the main element.
PHASE 2 - ITERATIONS Input data (Karamba): Plan width of the truss: 30 m Height of the structure: 35 m Load applied: Wind load and snowload included Section dimensions of the elements: 12x24 cm
V0 [3T]
Number of truss elements: 20 m Position of the two, truss suporting pillars: 10 Height of the base pillars: 3,1m Height of the trusses: from 1m to 2,9m
Deformations, momentums, tensions, compressions Displacements V0
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Ill. 3.10 Above, the physical models from phase three are shown together with some perspectives of the volume, that is created by the structure.
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Subsequent work
Subsequent to the workshop the structural system was then redone replacing the truss with simple beams. Furthermore, the front walls in the
church room was utilized to create spatial stability to horizontal loads.
Ill. 3.11 After having worked for a long time on the truss system it proved problematic when considering the thickness of the structure with at height of the truss of about 1.5 meters. After this a simpler beam system was attempted at proved itself very useful.
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The next step in the process was to optimize the structure, and use as little material as possible, this meant subdividing certain members into smaller
groups. These groups could then be utilized even more, instead of doing the dimensioning for the lowest denominator. This also helped solving the
problem of finding a solution to put the structure together, which was the finishing touches to the structure.
Ill. 3.12 On the pictures above, some sketches and a model in the process towards the finishing touch to structure joinery is shown.
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OVERALL PLAN
Initial phase
The overall plan for the project is another of the main elements in the design process. The process is again based on the design parameters, as well as the room program from the client. The program was very clear and was the governing factor in the layout of the plan. The initial phase of the composition of the plan went on how much the church could be divided into separate segments. The first proposals were characterized by falling
into two overall groups, the once scattering all the functions and the once collecting them into a compact building. Later on in the initial phase the overall plan started to take shape. The most effective way to progress with the plans was to clearly define a certain task or problem and timespan to do an investigative sketching phase focusing on that. At the end
of each phase it was extremely important to thoroughly sum up and evaluate the process and plan the next step, in order to keep the phase. The main tools for the preliminary design phase was of cause hand drawings. But in correlation with a very rough context model with all functions cut in simple foam blocks, to have an overview and a sense of scale.
Ill. 3.13 One of the methods in the planning of the overall plan was the usage of foam blocks applied on a working model. Above some of the overall function planning is shown using the block to create the right room connections according to the clients requests.
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Ill. 3.14 Another method used in the overall planning was sketches. Here some of the concepts in the planning of the functions are shown. Both variations of collecting the function in one building and as a scattered plan is shown.
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Courtyards and daylight
Further on in the process the building was dug down, in order to let the nature, roam the site, this did however create a few challenges. One is of cause the access to the building, to accommodate this focus was made on how open the facades of the building should be, and generally how the building meets the surrounding terrain. In extension to this there is in the nature
of things a challenge in how the building is lit up, when there are no facades. In order to accommodate the lack of daylight interior courtyards were introduced. The purpose of the courtyards was to light up the building, provide outdoor access for the users and create vertical connections both visually and for the nature. The proposals for dimensions and layout
of the courtyards were simulated in order to visualize the daylight factor in the room in need of daylight, this was done in an iterative process testing different arrangements. The daylight calculations were made within framework of requirement in certain rooms and prioritized list of what rooms are in need of daylight.
Ill. 3.15 On the pictures above, some of the iterations regarding the intake of light, among these the use of courtyards as a source of light. Also different degrees of burying the building is shown from partly to fully burial of the church.
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Ill. 3.16 Perspective drawings were made in order to state the expression of the the different degrees of burying of the church in Ill. 3.17 Also daylight simulations were used as a design criterion. relation to church tower. The discussion was whether to make the building grow out from the terrain or to cut it into it.
Detailing
The last touches to the overall plan was to focus on certain challenging details unique to the project. The solutions for these were made through iterations and in accordance to the
design parameters to and trying to solve them. The process behind the overall plan was not surprisingly using a lot of tools, with everything from calculations, hand sketching, modelling,
3d modelling etc. In addition to this it was found very effective to use different mood boards to describe what materials and feelings underling the different ideas.
Ill.3.18 One of the working methods when working on the sense, material, lights and experience in the different parts of the building was using mood boards. This made it possible to be very clear about what the desired feelings should be. Another part of the detailing process was to make the finishing touches on the challenging details. In order to do so, it was necessary to work in a psychical model, so the details could be treated more a more manageable way.
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Materials Materials has indirectly played a role in every single phase of this project. Wood was also already mentioned as a part of the analysis phase due to the history of local materials and the Nordic architecture approach. In the acoustic workshop also concrete was introduced. Concrete has a low absorption coefficient which makes it very reflective. In the church room the desirable reverberation time should be pretty high, and therefore it was decided to work a long
with these materials. Also, as described on the previous page, mood board were used as a tool, to describe the desired feeling and experiences. Along with this material were mentioned in relation to light and what effect the materials were wanted to create in this relations. On the basis all the experiences throughout the process a material workshop was held. The aim for this workshop was to combine the materials,
and determine which materials should be used, and where. The main objective of the material workshop was to stay honest in the usage of materials. That meant that all the materials should reflect the construction of the given element. The same was current for the choice of materials. In extension to the material studies, the material library has been used extensively in order to get a feel for the tactility in the materials.
Ill. 3.19 On the pictures above, some of the combinations in materials are shown. These were discussed and held up against the desires for being honest and the wanted sense.
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Developing the detail Another part of the detailing was structural and tectonic detailing approach. As a part of developing the detail, the meeting between the materials were opposed. For instance, the
meeting between the dug down walls and the walls facing the outside in the church were approached. Also the meeting between the walls and the
courtyards were discussed. These details were investigated in both sketches, detail drawing and in smaller working models.
Ill. 3.20 The pictures above show some of the working detail models and sketches, that were made to investigate the gathering between surfaces and materials.
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DETAILING THE SACRED PLACES
Church room
The church room and chapel has been undergoing a lot of different inputs from many parameters as a part of the integrated design process. The church rooms overall shape is mainly defined by quantitative parameters, but the feeling that is
1
wanted from the room is still not measureable. A lot of focus has been on how this feeling, defined earlier in the design phase, is kept alive in the room. The post processing of the room has been
focused on how the dominating high point of the roof could be emphasised in the indoor area. For this a light study was made in order to work with the experience inside the church, and how to emphasize the roof and volume.
3
2
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Ill. 3.21 Mainly the process of the church room stems from the acoustical and structural workshop, but another very important aspect was the interior and the lightning. Above some of the interpretations from this phase is shown. Picture one shows what sense the main goal was to create. Picture two shows different interior plans, which were, among others, assed in proportion to the clients desires and the function diagram mad in the analysis phase. Picture three shows some iterations of a window and light study.
Chapel The chapel on the other hand needed a different approach. The alterations in the design was focused on the journey to the chapel, how open it should be towards the nature and especially how the people inside should experience the
room. As the purpose of the room is more calm and personal than the church room, focus has been on making it an open room, with space for privacy and contemplation, and the sense in the room should appeal to being calm. The process
here is very closely related to the rest of the overall plan, due to the meeting with hallways, the courtyard, and its relation to the surrounding functions, and the journey from the entrance to the chapel.
Ill. 3.22 The approach of designing the chapel was made in continuation of the previously described phase. The mood boards served as a springboard for the desirable sense and experience in the room. After this a sketch of the desired feeling was made, which can be seen above. The journey from the main part of the church to the chapel was, as said earlier, an important design criterion, and above different sketches from that design detailing phase is shown.
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OUTDOOR Functions
The last focus point in the process is the outdoor area around and on top of the building, both because it was a central part of the design parameters and beacause it was one of the
requests in the competition material. The early part of the design process was focused on how separated building parts could be used to shape the access path to the building and frame it.
Besides the path aspects the outdoor program should also consist of a ceremonial space, a well-situated place to take photographs and a parking lot.
Ill. 3.23 Above, some of the sketches concerning the approach to the church is shown.
Paths
From the beginning it was very clear that the paths around the terrain should flow naturally with the terrain, and be naturally shaped by it.
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The first phase of outdoor design focused on the path and was put into three subcategories: a main path from parking lot to church, service
path and a meditative path.
Ill. 3.24 Above some of the sketches of the path is shown. They ask for creating several paths, that will give the spectator a journey around the site, building and nature.
Detailing
As well as the paths should use the terrain as a design parameter, the ceremonial site should use the natural inclination in the terrain. The paths going around the site was shaped so that they did not only go around the site, but also act as connections to the main road north of the site
and to the graveyard to the east. Through numerous iterations and layouts of the outdoor area, the design was changed in accordance with rules for for example turning circles, parking dimensions, disabled access and access by fire engines.
Furthermore, materials where discussed with the focus on how they could be used to mark differences and purposes of the infrastructure. The tools used in the process relied a lot on site and sun studies, working in model and 3D to understand the site and of cause sketching.
Connection to northen road
Connection to graveyard
Ceremonial place
Ceremonial place
Ill. 3.25 The pictures show the way the requirements for connections and incorporation of a ceremonial place and a mood board of inspiration.
Ill. 3.26 Above a mood board of material iteration is shown along with detailing of incorporation of parking ad technical requirements for turning space for cars in front of the building.
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CONCLUSION The process behind the final design, has been achieved trough an integrated design process. The beginning of the process was heavily influenced by a very performance based approach, which has also influenced the overall design process. The process in the different segments of the design process has generally been the same starting with explorative sketching and modelling which moved on to more elaborate and exact iterations which transformed into optimizations. A very crucial part of the process was the evaluations and conclusions. The most effective workshops and phases throughout the process was undouble the once that was the most
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thoroughly evaluated once as well. In extension to this a lot of the qualitative discussions were also more effective, when going back to the design parameters and very precisely formulating “What do we want?” instead of having discussions based subjective preferences arguing “What do I like?” Oppositely in the quantitative evaluations used in the more technical aspects of the process, they were very concrete and easy to agree on. Generally, the performance aided design process has speed up the initial design process significantly. Where as many would argue that the introduction of more technical aspects in the
design process are creating obstacles for the final design. But really if they are introduced early in the process, they could just as well be sources to input and help evaluate the design process. In extension to the performance aided design, the use of parametric design tools has helped the process a lot. Thanks to the parametric tool the link from input parameters for the design to the actual model and therefore evaluation has been speed drastically up. This means more iteration and therefore better optimization. Furthermore, the shorter time from input to model, also means that the design could be changed at a later phase than usually.
Parameters
Model
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HeightOfConerPillar HeightOfBackWalls LengthOfWalls AngleBetweenWalls
Structure
DebthOfCurves DebthOfCurves NumberOfBeams NumberOfCurvedBeams NumberOfPillars NumberWallElements Supports Restraints
Aestetics Overall
Model
Reflection
Acoustics Functionallity Context Rules Loads Site
Ill. 3.27 Diagram exemplifying the iterational workflow in the PAD process, in this case of the church room showing the design parameters
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04
EPILOGUE
CONCLUSION There has in this project been designed a new church for the Hatlehol community. The church is located on a hillside high in the landscape. With its curved shaped roof rising out of the terrain it functions as a beacon and a landmark in the landscape. This is however done in a delicate manner so that it does not compromise the nature on the site. The design of buildings interior arranges the many functions requested by the client, in a way to support the important connections between the different functions. This makes enables the building to be used to its full potential, allowing for simultaneously events in the building, and to expand the main church room for occasions where that need is present. At the same time the overall functions of the church are divided so that the sacred functions are not disrupted by the propane functions. At the same time the propane functions of the church are also separated into the administrative part, and the children’s part also accommodating the functions for the scouts. The outdoor spaces of the project have been designed to have as small impact on the existing
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terrain and possible. In extension to this the nature and natural terrain, have shaped the layout of the paths and the ceremonial site the terrain. This has been designed so that the paths flows with the terrain and becomes a natural part of it. The parking lot is placed on the southern edge of the site to preserve the nature, and make the journey towards the church as much of an experience as possible, staging the nature as well as slowly revealing the architecture. The entire complex is dimensioned in accordance to international Eurocode using Norwegian factors when it was possible, for example in calculating the snow load. Other dimensioning’s and calculations of the building has mainly been done in accordance to Danish legislations and standards. As an example is the building envelope calculated to accommodate the Danish requirements to in accordance to the energy class 2015. Also fire regulations and daylight requirements are satisfying in accordance to the Danish building code. The architectural style fits well within the principals of Nordic architecture, which is visible
in the usage of different materials not to mention the attention to the usage of light and the lack of it to. The Light is a central element in the project. The interior of the building I functionally lit up by carefully placed courtyards, supplying a sufficient amount of daylight to the functions in need of it. The light has also got an important effect in the sacred places. In the sacred functions the light is more as an effect to set a certain atmosphere. The church room is constructed through a performance aided design process combining goals set for acoustics and the structure, resulting in aesthetically strong and elegant architecture with satisfying acoustical properties supporting both speech and music. The room also uses traditional local materials and emphasises the fact the visitors are walking underground through the use of concrete. The smaller chapel are using the same materials as the church room. But in the chapel the different usage of light and overall proportions of the room creates a different atmosphere. In the chapel the design is created to provide a breeding ground for privacy and personal contemplation.
REFLECTION This project has truly introduced a new way of approaching a design process, as seen in the performance aided design process. It goes well in interaction with process behind the problem based learning, and is brilliant example of how what integrated design could be. Often the technical requirements to an architectural project is seen as a problem or an obstacle that has to overcome without it “ruining the project�. But if they are just introduced early enough in the process they can be used actively as a design parameter. When having the performance aspects of a building in mind early in the project they can provide quantitative results. Quantitative results can make selections and evaluations more effective and the overall process more goal orientated, and in the end help to create even better architecture. A way to have made the use of performance aided design even more effective could have been through better preparation. At the beginning of
the project there were three days to prepare for the workshop on acoustics. This workshop could have been even more effective, if the site and overall assignment had been thoroughly analysed. The performance aided design approach works very efficiently through the use of parametric design tools. With contribution from parametric design even models and calculations of it could be made at a much higher phase than through an analogue approach. Thus allowing for more iterations and a more effective process which again results opportunity to optimize the final building even more. This was possible through the entire process, right from the early experimentations to the last minimal optimizations. The many different tools make it even more important be very vigorous with organizing the process, and evaluating the results thoroughly. With the amount of data and input there is in the process, it is crucial to use it the right way. It was
proved throughout the process that the situations that was the most inefficient was also the once that was least organized. The process of optimizing the building in different aspects is of cause a never ending task, so there are of cause parts of the building that could have had some more attention if there had been more time. One of those is defiantly the structure of the church room were the focus has been on optimizing the curved beams in the six groups they were divided into. Whereas the top beams are only divided into two, here there is defiantly room for improvement. Furthermore, some aspects of the project are based on estimates e.g. the insulation in the building envelope is determined by simple u-value calculations. This is done without calculating the thermal indoor climate. Also the atmospheric and acoustic indoor climate is based on estimates.
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Nilsson, F., 2007, New Technology, New Tectonics? - On Architectural and Structural Expressions with Digital Tools, paper presented at Tectonics - Making Meaning. Conference Proceedings., Eindhoven University of Technology, Eindhoven, 10-12th December 2007.
Time and Date 2015, Time and Date A/S, Stavanger, accessed 8 November 2015, <http://www. timeanddate.com/sun/norway/alesund> Titelius, J., 2013, ArtOdysseys: Norway’s Historic Stave Churches EuroTravelogue, accessed 9
November 2015 <http://www.eurotravelogue.com/2013/08/Norways-Stave-Churches.html> WeatherSpark 2015, Cedar Lake Ventures Inc., San Francisco, accessed 8 November 2015, <https://weatherspark.com/averages/28840/ Alesund-M-re-og-Romsdal-Norway> World Weather and Climate Information 2015, World Wide Travel Organisation, Netherlands, Accessed 8 November 2015, <https://weather-and-climate.com/average-monthly-Rainfall-Temperature-Sunshine,alesund,Norway> Yr.no 2015, Norwegian Meteorological Institute and Norsk rikskringkasting AS (NRK), Oslo, accessed 8 November 2015, <http://www. yr.no/sted/Norge/M%C3%B8re_og_Romsdal/%C3%85lesund/%C3%85lesund/statistikk. html> Ålesund Kirkelige fellesråd, 2008, En åpen planog designkonkurranse for Hatlehol Kykje, Ålesund Ålesund Kommune, 2015, Ålesund Kommune, Ålesund, accessed 9th November 2015, < h t t p : / / w w w. a l e s u n d . k o m m u n e . n o / f a k ta-om-alesund/om-byen/byhistorie/tidsreise>
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Illustations All illustrations are own illustrations exept the following: 1.12 credits: JVA Architects <http://www.jva.no/ projects/small/nappskaret.aspx#> 1.13 credits: JVA Architects <http://www.jva.no/ projects/small/nappskaret.aspx#> 1.14 credits: Snohetta <http://snohetta.com/ project/42-norwegian-national-opera-andballet> 1.15 credits: Lundgaard & Tranberg <http://www.ltarkitekter.dk/skuespilhuset/ t8rljd6nvqz5h9s8rmrf7qzahwfymg> 2.13 credits: Arrowway Textures, 2015, concrete-19_d100, <https://www.arrowaytextures.ch/> 2.14 credits: texturelib.com <http://texturelib. com/#!/category/?path=/Textures/wood/ planks%20new> edt. Own illustration 2.15 credits: texturelib.com <http://texturelib. com/#!/category/?path=/Textures/wood/ planks%20new> 5.2 credits: architettura-italiana.com <http:// architettura-italiana.com/projects/299811primus-architects-stamers-kontor-forest-house>
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APPENDIX
APPENDIX 1
Room program
Room program
Type of rooms Sacred rooms Church room
Number of rooms Size 1
Mezzanine
Sum m2 500 seats
750 m2
15-30 people
75 m2
Childrenâ&#x20AC;&#x2122;s chapel
1
20-30 people
40 m2
Chapel
1
20-30 people
80 m2
Cloister room
1
Sacristy for baptism
1
5-10 people
40 m2
Metting room
1
2 -5 people
25 m2
Sacrity
1
2 people
12 m2
12 m2
Common room Additional sacristy
1
16 m2
Entrance hall
1
100 m2
Storage
3
For chairs and books
60 m2
Church hall
1
20-40 people
80 m2
Congregation hall
1
50-100 people
150 m2
Kitchen 104
Administation
45 m2
Church hall
1
20-40 people
80 m2
Congregation hall
1
50-100 people
150 m2
Room program Kitchen
Type of rooms Sacred rooms Administation Church room
45 m2
Number of rooms Size
Sum m2
1 6-8
500 seats
750 60 m2
Mezzanine Metting/dining
1
15-30 8 people
75 25 m2
Childrenâ&#x20AC;&#x2122;s chapel
1 2
20-30 people
40 10 m2
Chapel Wardrobe/entrence
1
20-30 people
80 10 m2
Cloister Technicalroom room
1
Sacristy for baptism
1
5-10 people
40 m2
Metting room Other rooms
1
2 -5 people
25 m2
Sacrity Class room
1 2
2 people 10-15
12 50 m2
Music room
1
10-15 people
25 m2
Common room Activity room
12 35 m2
1
35 m2
Additional Storage sacristy
1
16 10 m2
Entrance Refuse hall
1
100 12 m2
Storage Workshop
3 1
For chairs and books
60 20 m2
Church Laundryhall room
1
20-40 people
80 10 m2
Congregation Public toilet hall
1 5
50-100 people
150 28 m2
Kitchen Drainroom
45 30 m2
Administation I alt
1845 m2 6-8
60 m2
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APPENDIX 2 Fire regulations
According to the Danish fire regulations, the building should refer to a specific usage category, which in this case is usage category 3: Usage category 3 compromises buildings in which the mainly stay is during the daytime for many people. Also it must be assumed, that the people in building do not necessary has knowledge of the buildings emergency exits, but they are still capable of bringing themselves to safety. (Bygningsreglementet, Energistyrelsen 2014) Evacuation should be possible effortless and with a directly path to either a secure fire section/cell or to the outside of the building. They maximal distance to an escape route should not surpass 25m from any given point in the room. Besides there should always be at least one additional evacuation path to the main
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escape route, e.g. a window, in case of blocking of the primary fire escape route. The two possible fire escape routes should be independent, which they are when they are minimum 5 m separated. Furthermore, the amount of paths to escape routes should be dimensioned from the anticipated amount of people using the given room. A fire escape could be one of the following: • A door to the terrain • A door to a fire escape hall in another fire cell/ section, wherefrom there is access to the outside or a fire escape staircase • A door to a fire escape staircase that leads to the outdoor terrain A door to a main escape path should always at least have a width of 77 cm, but in places with many persons located the same place, the width
is recommended not to be under 10 mm per person of which the room is dimensioned to. The total of this width should be distributed to all of the primary fire exits. Moreover, the doors in room with a lot of people which is over 150 m2 is endorsed to be double doors and the door must in the direction of the escape. According to the fire regulations the min. floor area in usage category 3 in room with chair arrangements, which in this case would be e.g. the church room, is suggested to 1,0 mm2 per person. Escape way paths should at least be 1,3 m in width, but not less than 10 mm per person using the room. (Bygningsreglementet, Energistyrelsen 2014)
Escape routes Emergency exits Fire sections Escape routes Ill. 5.1 Evacuation plan
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APPENDIX 3 Iron sulfate
This material can be used as priming paint on wooden materials, mostly it’s applied on spruce and pine. Iron sulfate helps the wood to be more tough against hard weather, as rain and sun. the treatment gives the wood color nuances of silver and grey and reminds of a untreated wooden façade after a few years. This kind of treatment has a long tradition in the Norwegian building history and it’s only become more popular over the years. (Norsk Treteknisk Institutt 2012)
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Ill. 5.2 Pine treated with iron sulfate
APPENDIX 4 Loads
Load combinations
The structural system of the church has been build as a finite-element-model (FEM) and therefrom been calculated. The impact from the loads working on the system can be determined from the load combinations calculated according to ultimate limit state (ULS), given by:
Loads
On the diagram ill. 5.3 the loads working on the system can be seen. Because of the dramatic sloping of the roof, it has been necessary to calculate a special snow load. It has therefore been divided into two part: one that has been calculated with an angle above 60 degrees, which therefore means no snow affecting the loads, and one that has been calculated as a flat roof. The snow from the +60o part of the roof will slide to the lower part of the roof, which means that the snow load impact in this section will be bigger, and therefore itâ&#x20AC;&#x2122;s calculated as a flat roof as an extra percussion . The division of the roof can be seen on ill. 5.3.
Snow load
and serviceability limit state (SLS), given by: Dead load
The combination factors are given by the dominating load in a combination, and in this case the system has been calculation in two cases â&#x20AC;&#x201C; dominating wind load and dominating snow load, in both ULS and SLS. Following combination factors has been used according to Eurocode0:
Following partial factors has been used: Ill. 5.3 Structure with loads
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Structual behavior
Ill. 5.4 On the drawing stated above, the deformation of the structural system is shown.
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Ill. 5.5 This illustration shows how the stresses are spread in the structural system, given by a Karamba analysis. The tension is given by blue colour, and compression is marked by the red colour.
Member verification in Robot On this page, the member verification from Robot is shown. On the diagram, the ratio usage of the beams is shown. This shows that a huge part of the beams has a usage percentage under 50 %, but it also shows that a big part of the beams in the roof has a high usage percentage. On the scheme stated below, a list of the members, which has a ratio usage above 90% is mentioned. This substantiate that the highest stress must be in the beams in the roof part, which may be caused by the way, that the loads affects the structural behaviour, as mentioned earlier.
Member Curved beam top 1st curved beam Curved beam bottom Front wall element Curved beam bottom 1st curved beam Curved beam bottom 2nd curved beam 2nd curved beam 3rd curved beam Curved beam bottom 1st curved beam 1st curved beam 4th curved beam 3rd curved beam 1st curved beam 1st curved beam 1st curved beam
Material GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h GL32h
Lay 69,98 16,45 18,92 7,09 18,4 16,45 19,13 22,32 22,32 32,25 18,4 16,45 17,1 43,42 32,25 17,1 16,91 16,45
Laz 69,98 25,85 27,9 7,09 27,14 25,85 28,22 37,2 27,2 56,44 27,14 25,85 26,88 26,57 28,22 56,44 56,44 75,26
ratio 0,99 0,99 0,98 0,97 0,97 0,96 0,95 0,95 0,95 0,94 0,94 0,93 0,93 0,93 0,91 0,91 0,9 0,9
Ratio <0,5 Ill. 5.6 Diagram showing the utilization ratios of structure members in the church room
>0,5
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APPENDIX 5 Rest of the building
As mentioned in the Analysis part this project included not only the structural design of the church room but also the structural conept for the rest of the building. The need of using reinforced conrete for the retaining wall made the whole situation less complicated. It is beacuse of this that the external restrains were closed in two types of supports: base of the collumn and the external beamsâ&#x20AC;&#x2122; supports on the top of the wall. Sizes of the beam and distances between them helped in the design process by keeping visible grids of the rooms in the plan. The only one change in the almost repetetive language of the structural system was made in congregation hall were the middle pillar had to be moved to the wall to make the whole space clean from vertical structural elements.
COMPARING KARAMBA AND ROBOT OVERALL RESULTS
PHASE 1 PHASE 2 PHASE 3
KARAMBA RESULTS MAX. DISPLACEMENT MAX. MOMENTUM MAX. TENSION [mm] [kN] [kNm] 32,0 1,07 38,46 20,9 2,54 59,06 21,47 3,12 61,54
PHASE 1 PHASE 2 PHASE 3
ROBOT RESULTS MAX. DISPLACEMENT MAX. MOMENTUM MAX. TENSION MAX. COMPRESION WEIGHT [mm] [kN] [kNm] [t] [kN] 204,24 160 45,94 62,7 381,75 186,96 66 59,87 66,4 373,87 179,09 72 55,52 56,7 388,31 MAX. COMPRESION WEIGHT [t] [kN] 376,56 62,7 383,71 66,4 363,66 56,7
In the first phase, C30 class of wood was taken into the consideration. Because of the big snowload, roof and usability vertical forces structure was very dense of the beams at the beginning with the goal to make the elements small as possible. However results has shown that it is not only not enough (24 elements had ratio above 1) but also in many cases not very effective - 7,9% of elements had ratio below 0,1 and 20,19% of elements had ratio between 0,1 and 0,2. In the second phase it was all about delivering more solid structure which in first place will try to remove elements with ratio above 1. It meant to rise the sizes of the elements but also add special pillars in the congregation hall where the span was just too big to handle with not only the previous sized primary beams but also standard pillars. In adition wood class has been changed to GL32H This resulted with only one element with ratio above 1 (which was not in the congregation hall) however even more elements started to be not effective. Even though 7,08% (less) of elements had ratio below 0,1, much more elements had ratio between 0,1 and 0,2 - 27,84%. So thatâ&#x20AC;&#x2122;s why last phase focused on optimalisation of the structure. It required a bit more elements but resulted with smaller sizes of the structural elements. What is more at the end there were no elements with ratio above 1 and also efficiencies of the elements were drasticly higher - 2,88% of elements had ratio below 0,1 and 12,63% had ration between 0,1 and 0,2.
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Ill. 5.7 Scheme of the structural idea in the rest of the building
PHASE 1
RANGE OF RATIOS: NUMBER OF ELEMENTS: 0 - 0,09 58 0,1 - 0,19 148 0,2 - 0,29 177 0,3 - 0,39 119 0,4 - 0,49 78 0,5 - 0,59 58 0,6 - 0,69 41 0,7 - 0,79 9 0,8 - 0,89 10 0,9 - 0,99 11 >1,00 24 TOTAL: 733
PHASE 2
RANGE OF RATIOS: NUMBER OF ELEMENTS: 0 - 0,09 36 0,1 - 0,19 142 0,2 - 0,29 85 0,3 - 0,39 77 0,4 - 0,49 55 0,5 - 0,59 41 0,6 - 0,69 28 0,7 - 0,79 11 0,8 - 0,89 31 0,9 - 0,99 3 >1,00 1 TOTAL: 510
PHASE 3
Ill. 5.8 Diagram showing the utilization ratios of structure members in the rest of the complex.
RANGE OF RATIOS: NUMBER OF ELEMENTS: 0 - 0,09 16 0,1 - 0,19 70 0,2 - 0,29 122 0,3 - 0,39 103 0,4 - 0,49 92 0,5 - 0,59 45 0,6 - 0,69 51 0,7 - 0,79 30 0,8 - 0,89 19 0,9 - 0,99 6 >1,00 0 TOTAL: 554
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MEMBER 23 26 182 181 25 289 180 183 407 162 161 24 179 184 160 171 172 173 163 166 167 266 256 170 159 246 178 189 174 260 269 455 185 403 276 499 1 250 188 164 237 275 406 157 328 176 508 304 521 147 146 283 442 169 622 268 490 235 512 517 618 195 231 230 571 570 494 493 484 485 140 141
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PHASE 1 - ORIGINAL STRUCTURE HIGHEST RATIOS SECTION MATERIAL LAY LAZ RATIO CASE PILLARS C30 43.30 43.30 1.71 4 SNOWLOAD COMB PILLARS C30 43.30 43.30 1.56 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 1.49 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 1.49 4 SNOWLOAD COMB PILLARS C30 43.30 43.30 1.47 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 1.46 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 1.44 4 SNOWLOAD COMB C30 8.95 17.90 1.43 4 SNOWLOAD COMB SECONDARY_BEAMS SECONDARY_BEAMS C30 7.69 15.38 1.33 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.28 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.28 4 SNOWLOAD COMB PILLARS C30 43.30 43.30 1.27 4 SNOWLOAD COMB C30 8.95 17.90 1.27 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 1.24 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.16 14.32 1.22 4 SNOWLOAD COMB PRIMARY_BEAMS PRIMARY_BEAMS C30 7.16 14.32 1.19 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.19 4 SNOWLOAD COMB C30 7.16 14.32 1.16 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.16 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.13 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 1.09 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.04 14.07 1.04 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 1.04 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.16 14.32 1.03 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 0.98 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.04 14.07 0.97 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 0.96 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.30 16.60 0.96 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.16 14.32 0.94 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.85 15.70 0.94 4 SNOWLOAD COMB SECONDARY_BEAMS SECONDARY_BEAMS C30 7.85 15.70 0.94 4 SNOWLOAD COMB TETIARY_BEAMS C30 26.85 53.69 0.94 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.95 17.90 0.93 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 0.90 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.85 15.70 0.90 4 SNOWLOAD COMB TETIARY_BEAMS C30 29.23 58.46 0.89 4 SNOWLOAD COMB PILLARS C30 43.30 43.30 0.87 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.85 15.70 0.87 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 0.86 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 0.85 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.23 16.45 0.85 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 0.84 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.69 15.38 0.82 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 0.80 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.18 16.36 0.80 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 0.79 4 SNOWLOAD COMB TETIARY_BEAMS C30 29.23 58.46 0.79 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.18 16.36 0.76 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.75 4 SNOWLOAD COMB PRIMARY_BEAMS C30 29.16 58.31 0.74 4 SNOWLOAD COMB PRIMARY_BEAMS C30 29.16 58.31 0.74 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.85 15.70 0.74 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.71 4 SNOWLOAD COMB PRIMARY_BEAMS C30 7.16 14.32 0.70 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.69 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.07 14.15 0.68 4 SNOWLOAD COMB TETIARY_BEAMS C30 29.23 58.46 0.67 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.85 15.70 0.67 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.66 4 SNOWLOAD COMB TETIARY_BEAMS C30 29.23 58.46 0.66 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.65 4 SNOWLOAD COMB SECONDARY_BEAMS C30 8.30 16.60 0.65 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.04 14.07 0.64 4 SNOWLOAD COMB SECONDARY_BEAMS C30 7.07 14.15 0.64 4 SNOWLOAD COMB TETIARY_BEAMS C30 54.67 109.34 0.64 4 SNOWLOAD COMB TETIARY_BEAMS C30 54.67 109.34 0.64 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.64 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.64 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.63 4 SNOWLOAD COMB TETIARY_BEAMS C30 46.55 93.10 0.63 4 SNOWLOAD COMB PRIMARY_BEAMS C30 3.24 6.48 0.63 4 SNOWLOAD COMB PRIMARY_BEAMS C30 3.24 6.48 0.63 4 SNOWLOAD COMB
MEMBER 118 135 298 299 280 297 120 300 281 279 100 37 134 122 296 127 133 131 278 129 125 327 124 119 123 132 341 121 130 128 126 438 151 245 243 317 679 437 418 419 302 61 277 339 378 730 311 74 722 675 731 732 733 16 351 382 352 600 725 723 729 724 726 671 727 728 80 667 655 6 415 417
PHASE 1 - ORIGINAL STRUCTURE LOWEST RATIOS SECTION MATERIAL LAY LAZ RATIO PRIMARY_BEAMS C30 5.66 11.32 0.01 PRIMARY_BEAMS C30 3.85 7.70 0.01 SECONDARY_BEAMS C30 9.53 19.05 0.01 SECONDARY_BEAMS C30 9.53 19.05 0.01 SECONDARY_BEAMS C30 9.53 19.05 0.01 SECONDARY_BEAMS C30 9.53 19.05 0.02 PRIMARY_BEAMS C30 4.84 9.67 0.02 SECONDARY_BEAMS C30 9.53 19.05 0.02 SECONDARY_BEAMS C30 9.53 19.05 0.02 SECONDARY_BEAMS C30 9.53 19.05 0.02 PRIMARY_BEAMS C30 15.59 31.18 0.02 PRIMARY_BEAMS C30 14.72 29.44 0.02 PRIMARY_BEAMS C30 2.63 5.26 0.02 PRIMARY_BEAMS C30 4.02 8.03 0.02 SECONDARY_BEAMS C30 9.53 19.05 0.02 PRIMARY_BEAMS C30 4.11 8.21 0.03 PRIMARY_BEAMS C30 3.91 7.83 0.03 PRIMARY_BEAMS C30 3.98 7.95 0.03 SECONDARY_BEAMS C30 9.53 19.05 0.03 PRIMARY_BEAMS C30 4.04 8.08 0.03 PRIMARY_BEAMS C30 3.28 6.57 0.03 SECONDARY_BEAMS C30 7.69 15.38 0.03 PRIMARY_BEAMS C30 3.19 6.39 0.03 PRIMARY_BEAMS C30 0.82 1.64 0.03 PRIMARY_BEAMS C30 2.46 4.93 0.03 PRIMARY_BEAMS C30 2.57 5.13 0.03 SECONDARY_BEAMS C30 8.18 16.36 0.04 PRIMARY_BEAMS C30 1.64 3.28 0.04 PRIMARY_BEAMS C30 2.50 5.00 0.04 PRIMARY_BEAMS C30 2.44 4.88 0.04 PRIMARY_BEAMS C30 2.37 4.75 0.04 SECONDARY_BEAMS C30 7.69 15.38 0.05 PRIMARY_BEAMS C30 15.30 30.60 0.06 SECONDARY_BEAMS C30 8.23 16.45 0.06 SECONDARY_BEAMS C30 8.23 16.45 0.06 SECONDARY_BEAMS C30 7.69 15.38 0.06 TETIARY_BEAMS C30 27.60 55.21 0.07 SECONDARY_BEAMS C30 7.69 15.38 0.07 SECONDARY_BEAMS C30 7.58 15.16 0.07 SECONDARY_BEAMS C30 7.58 15.16 0.07 SECONDARY_BEAMS C30 8.30 16.60 0.08 PRIMARY_BEAMS C30 15.59 31.18 0.08 SECONDARY_BEAMS C30 9.53 19.05 0.08 SECONDARY_BEAMS C30 8.18 16.36 0.08 SECONDARY_BEAMS C30 8.30 16.60 0.09 TETIARY_BEAMS C30 29.23 58.46 0.09 SECONDARY_BEAMS C30 8.30 16.60 0.09 PRIMARY_BEAMS C30 15.59 31.18 0.09 TETIARY_BEAMS C30 29.23 58.46 0.09 TETIARY_BEAMS C30 27.60 55.21 0.09 TETIARY_BEAMS C30 29.23 58.46 0.09 TETIARY_BEAMS C30 29.23 58.46 0.09 TETIARY_BEAMS C30 29.23 58.46 0.09 PILLARS C30 43.30 43.30 0.09 SECONDARY_BEAMS C30 7.58 15.16 0.09 SECONDARY_BEAMS C30 8.30 16.60 0.09 SECONDARY_BEAMS C30 7.58 15.16 0.09 TETIARY_BEAMS C30 28.69 57.37 0.09 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 27.60 55.21 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 TETIARY_BEAMS C30 29.23 58.46 0.10 PRIMARY_BEAMS C30 24.83 49.65 0.10 TETIARY_BEAMS C30 27.60 55.21 0.10 TETIARY_BEAMS C30 27.60 55.21 0.11 PILLARS C30 43.30 43.30 0.11 SECONDARY_BEAMS C30 8.18 16.36 0.11 SECONDARY_BEAMS C30 7.58 15.16 0.11
CASE 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB 4 SNOWLOAD COMB
MEMBER 231 141 117 118 389 405 155 154 156 397 412 381 507 453 319 422 116 119 465 417 456 510 450 459 162 373 349 439 445 441 443 447 365 357 437 153 207 213 157 142 508 150 106 133 105 220 509 171 286 104 115 107 1 120 137 136 221 215 293 146 147 138 108 209 145 103 124 123 196 48 109 152
PHASE 2 - MAKING STRONGER STRUCTURE HIGHEST RATIOS SECTION MATERIAL LAY LAZ RATIO CASE SECONDARY_BEAMS GL32H 6.89 13.79 1.03 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.92 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 2.99 5.55 0.91 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 2.99 5.55 0.91 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.88 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.88 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.88 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.87 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.87 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.87 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.86 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.86 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.86 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.85 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.85 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.85 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.85 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.85 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.85 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.84 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.84 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.83 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.83 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.11 14.23 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.81 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.81 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.81 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.81 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.81 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.80 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.79 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 6.89 13.79 0.78 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 6.89 13.79 0.78 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.78 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.78 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.72 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.72 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 3.79 7.04 0.71 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.71 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 2.19 4.07 0.71 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 6.89 13.79 0.70 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.69 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.81 17.63 0.69 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 6.89 13.79 0.69 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.34 8.06 0.69 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.69 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 3.46 6.42 0.68 4 SNOWLOAD COMB PILLARS GL32H 43.30 43.30 0.68 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.68 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.68 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.68 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.69 15.38 0.67 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.69 15.38 0.67 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.67 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.66 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.66 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.66 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 2.52 4.68 0.65 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.69 15.38 0.64 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.64 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 1.64 3.05 0.64 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 26.91 49.98 0.63 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 26.91 49.98 0.63 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 6.89 13.79 0.63 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.38 41.57 0.62 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.73 8.78 0.62 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.61 4 SNOWLOAD COMB
MEMBER 229 228 82 230 211 212 239 177 210 290 256 76 462 58 46 261 29 16 302 241 264 299 247 267 132 300 251 34 65 39 301 362 33 38 6 281 289 265 63 258 216 262 64 312 313 78 243 277 279 77 263 88 317 316 275 25 26 70 27 219 18 505 45 307 205 266 303 499 501 506 44 287
PHASE 2 - MAKING STRONGER STRUCTURE LOWEST RATIOS SECTION MATERIAL LAY LAZ RATIO CASE SECONDARY_BEAMS GL32H 13.61 27.22 0.02 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.61 27.22 0.02 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.02 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.61 27.22 0.02 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.61 27.22 0.02 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.61 27.22 0.03 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.03 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.81 17.63 0.04 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.61 27.22 0.04 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.05 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.05 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.38 41.57 0.05 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 93.10 186.20 0.05 1 DEADLOAD PRIMARY_BEAMS GL32H 15.99 29.69 0.06 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.06 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.06 4 SNOWLOAD COMB PILLARS GL32H 43.30 43.30 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.07 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.07 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.07 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.07 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.07 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.07 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.07 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.05 31.67 0.07 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.08 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.05 31.67 0.08 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.08 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 29.23 58.46 0.08 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 10.13 18.81 0.09 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 10.13 18.81 0.09 4 SNOWLOAD COMB PILLARS GL32H 43.30 43.30 0.09 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.58 15.16 0.09 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.81 17.63 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 11.19 20.78 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.59 32.66 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.52 21.03 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.58 15.16 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 7.58 15.16 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.80 8.91 0.10 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.85 9.00 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 45.83 85.12 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 45.83 85.12 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 45.83 85.12 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.81 17.63 0.11 4 SNOWLOAD COMB PILLARS GL32H 43.30 43.30 0.11 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 32.48 64.95 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 11.19 20.78 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.81 17.63 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.66 17.32 0.11 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 32.48 64.95 0.12 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 32.48 64.95 0.12 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 32.48 64.95 0.12 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.12 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 8.24 16.48 0.12 4 SNOWLOAD COMB
MEMBER 236 161 160 162 123 122 124 551 121 159 125 163 241 257 180 300 305 222 231 554 552 147 390 317 417 307 237 169 553 458 320 427 436 428 437 418 353 204 419 382 112 452 111 265 230 409 391 173 410 460 400 156 175 366 139 148 464 218 205 110 401 113 371 306 373 372 466 355 374 246 454 239
PHASE 3 - FINAL OPTIMALISATION HIGHEST RATIOS SECTION MATERIAL LAY LAZ RATIO CASE SECONDARY_BEAMS GL32H 12.28 24.56 0.97 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.95 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.95 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.95 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.90 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.90 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.89 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.87 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.86 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.85 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 5.98 11.11 0.85 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.85 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.71 21.41 0.84 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.71 21.41 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.22 22.44 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.83 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.83 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.83 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.82 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 33.40 66.81 0.82 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.82 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 33.40 66.81 0.80 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.79 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.42 22.83 0.79 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.77 4 SNOWLOAD COMB CH_PILLARS GL32H 31.49 31.49 0.77 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 41.65 83.30 0.76 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.76 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.73 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.73 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.73 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.73 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.72 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.72 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.64 19.29 0.72 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.72 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.72 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 3.79 7.04 0.72 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 41.65 83.30 0.72 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 2.19 4.07 0.71 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.71 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.64 19.29 0.71 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.71 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.71 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.71 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.71 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 75.47 150.94 0.71 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.71 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.70 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.70 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.70 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.70 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.34 13.64 0.69 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 41.65 83.30 0.69 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.69 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.69 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.34 8.06 0.69 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 74.85 149.70 0.69 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 3.46 6.42 0.68 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.68 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.68 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.68 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.68 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 75.47 150.94 0.67 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.67 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 63.10 126.19 0.67 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.67 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 75.47 150.94 0.67 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 12.28 24.56 0.67 4 SNOWLOAD COMB
MEMBER 247 84 47 54 66 40 312 318 184 73 16 138 71 72 39 38 85 86 274 329 271 53 52 186 266 46 45 78 94 249 326 327 277 89 103 65 64 328 99 193 87 311 88 199 18 260 17 256 83 240 6 297 28 302 15 219 223 228 543 310 309 77 545 292 59 549 550 299 548 546 187 272
PHASE 3 - FINAL OPTIMALISATION LOWEST RATIOS SECTION MATERIAL LAY LAZ RATIO CASE SECONDARY_BEAMS GL32H 10.48 20.97 0.04 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.38 41.57 0.05 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.05 31.67 0.05 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.06 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.06 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.05 31.67 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.06 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.22 22.44 0.07 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.07 4 SNOWLOAD COMB PILLARS GL32H 49.49 49.49 0.08 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 15.99 29.69 0.08 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.09 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 11.19 20.78 0.09 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 10.13 18.81 0.09 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.92 42.56 0.09 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 4.80 8.91 0.10 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 17.59 32.66 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.02 22.04 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.02 22.04 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 11.19 20.78 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.22 22.44 0.11 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 10.13 18.81 0.11 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.92 42.56 0.12 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.12 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 3.17 5.88 0.12 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.12 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.12 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.12 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.02 22.04 0.13 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.13 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 7.29 13.53 0.13 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 11.19 20.78 0.13 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.13 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.02 22.04 0.13 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 10.38 19.28 0.13 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.14 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.14 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.14 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.14 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.14 4 SNOWLOAD COMB PILLARS GL32H 49.49 49.49 0.14 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.02 22.04 0.14 4 SNOWLOAD COMB PILLARS GL32H 49.49 49.49 0.15 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.15 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.15 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.16 4 SNOWLOAD COMB PILLARS GL32H 49.49 49.49 0.16 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.16 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 22.92 42.56 0.16 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.16 4 SNOWLOAD COMB PILLARS GL32H 49.49 49.49 0.16 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.16 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 11.22 22.44 0.17 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.17 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.17 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.17 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 10.48 20.97 0.17 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 23.45 43.55 0.17 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.17 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.17 4 SNOWLOAD COMB PRIMARY_BEAMS GL32H 27.18 50.48 0.17 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.17 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.17 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.64 19.29 0.17 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.18 4 SNOWLOAD COMB TETIARY_BEAMS GL32H 37.12 74.23 0.18 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 9.05 18.11 0.18 4 SNOWLOAD COMB SECONDARY_BEAMS GL32H 13.38 26.77 0.18 4 SNOWLOAD COMB
115
pillars
beams
< 320 >
<400 >
< 480 >
< 600 > < 400 >
< 300 >
< 240 >
< 160 >
member 1.01
member 1.02
member 1.03
member 1.04
pillars
primary beams
secondary beams
tridary beams
width: 400 mm height: 400 mm
width: 300 mm height: 600 mm
width: 240 mm height: 480 mm
width: 160 mm height: 320 mm
PHASE 2
beams
PHASE 3
< 320 >
< 400 >
<550 >
< 650 >
pillars
< 560 >
PHASE 1
< 550 >
< 400 >
< 350 >
< 280 >
< 160 >
member 1.01.1
member 1.01.2
member 1.02
member 1.03
member 1.04
congregation hall pillars
pillars
primary beams
secondary beams
tridary beams
width: 550 mm height: 550 mm
width: 400 mm height: 400 mm
width: 350 mm height: 650 mm
width: 280 mm height: 560 mm
width: 160 mm height: 320 mm
beams
116
< 280 >
< 350 >
< 440 >
<550 >
< 650 >
pillars
< 550 >
< 350 >
< 350 >
< 220 >
< 140 >
member 1.01.1
member 1.01.2
member 1.02
member 1.03
member 1.04
congregation hall pillars
pillars
primary beams
secondary beams
tridary beams
width: 550 mm height: 550 mm
width: 350 mm height: 350 mm
width: 350 mm height: 650 mm
width: 220 mm height: 440 mm
width: 140 mm height: 280 mm
Ill. 5.9 Size of the structureâ&#x20AC;&#x2122;s members
APPENDIX 6
E
Detail E - 1:20
1. W2 15 2x waterproof membrane 100 PIR thermal insulation - Vapor proof membrane 350 Reinforced concrete with polished surface
2.
3. 4. 5.
1. 30mm Reinforced concrete wall 2. Bedrock stones (layer will vary around 30cm of width) connected together with mortar as well as to the reinforced concrete wall 3. Waterproof membrane 4. 120mm of PIR thermal insulation 5. 80x150mm curtain wall aluminum system
W2
Detail E
Ill. 5.11 Detail D 1:20
117
Detail F - 1:20
F
W2
1.
F1
2.
3. 4.
F1 50 Concrete - Protection layer 120 PIR thermal insulation 200 Reinforced concrete - Waterproof membrane 50 Flatting light concrete layer 30 Lime sand W2 15 2x waterproof membrane 100 PIR thermal insulation - Vapor proof membrane 350 Reinforced concrete with polished surface 1. 20x50mm dilatation 2. Reinforced concrete foundation 3. Light concrete - alignment layer 4. Floor heating in concrete layer
Detail F Ill. 2.30 Detail F 1:20
118