tmiber truncated icosahedron as an educational tool in architecture
Transcription
tmiber truncated icosahedron as an educational tool in architecture
TMIBER TRUNCATED ICOSAHEDRON AS AN EDUCATIONAL TOOL IN ARCHITECTURE Atsushi TABUCHI1, Shinsak MUNEMOTO2 ABSTRACT: We are dveloping an educational tool in Architecture by using timber materials. Timber is easy to deal with. In this paper, it was reported that out line the workshop which was the educational opportunity for students in department of environmental design, Kyoto prefectural university, and truncated icosahedron, which is a soccer ball shape, as a tool for this workshop. It was expected that the effects of this workshop was 1)a geometric trainign, 2)feeling timber materials, 3)designing structures, 4)trying to manage a schedule. KEYWORDS: self-built architechture, timber design, workshop, educational tool 1 INTRODUCTION 123 Kyoto Prefectural University (KPU) is located at Shimogamo, about several kilometers north of city center of Kyoto. Some World heritages, Shimogamo and Kamigamo shrines, Kinkaku-ji temple and Ginkaku-ji temple are located near KPU. In this university, an architectural technology is held at department of environmental design of faculty of life and environmental sciences. In addition to architecture, landscape, product and apparel design etc. are educated because it is thought that the view of ordinary citizens and environmental conservaton were needed for the future of architecture. This depertment has the feature which students can learn a broad range around architecture, but each learning tended to be fragmented for students. Therefore, students are sometimes hard to image an overview of architecture. A wide spleading range of an education is like to cut two ways, advantages and disadvantages. We are developping an educational tool in Architecure by using timber materials in order to educate and train students on an architectural design which is not only aesthetic but also structural, scheduling and management. 2 EDUCATIONAL SYSTEM IN KPU 2.1.1 ADMISSION POLICY In this department of Kyoto Prefectural University, the following educational philosophy is set, “The main objective of this department is nurturing of the 1 Atsushi TABUCHI, Graduate School of Life Science and Environmental Science, Kyoto Prefectural University, 1-5 Shimogamo-nakaragi-cho, Sakyo, Kyoto, Japan Email: [email protected] 2 Shinsaku MUNEMOTO, Graduate School of Science and Engineering, Ritsumeikan University, 1-1-1 Noji Higashi, Kusatsu, Shiga, Japan, Email: [email protected] 3 professionals who are capable of creating living environment and lifestyles friendly to both people and the environment by applying their abundant knowledge and comprehensive judgment based on expertise in housing and architectonics. The department is characterized by significant enhancement of its technical education for better supporting students in gaining qualification as a first-class registered architect, and also by research and education on the viewpoints of ordinary citizens as well as on environmental conservation including landscape conservation, afforestation, etc..” 2.2 PROGRAM In order to achive that objective of this depertment, we educate students by four categories, strructure & building production, architecutural environment & equipment, planning & design, landscape design. As a matter of course, fundamental education ,which is mathematics, physics and social science etc., was offerd.The program of this depertment was shown in Table 1. 3 WORKSHOP 3.1 INTENDED STUDENTS Main target of students who joined in this workshop was 4th grade who were on first semester soon after end of 3rd grade. Students learned almost all knowledges about architectures but did not image an overview of architechture. Students who joined this workshop associated each fragmented knowledges. 3.2 ANTICIPATED EFFICACY Topics of this workshop are followings; 1. Geometric training: An architectural design is needed understanding relationship between each spaces. So a regular body or a semiregular body was chosen as the model in this workshop. 2. Feel timber material: An education about timber is not so much details as steel and concrete in Table 1: Educational program in this department 1st Grade 2nd Grade ・Outline of Environmenal Design ・Reding Scientific Papres 1 ・Fundamental Mathematics 1&2 ・Statistics ・Fundamental Physics1&2 ・Fundamental Chemistry1 ・Fundamental Biology1 ・Fundamental Earth Science1 ・Practice in Environmental Design1&2 ・Professional Awareness and Ethic ・Introduction to Buiding Structures Common Subject Strructure & building Production ・Environmental Physics 3rd grade 4th grade ・Applied Mathematics1&2 ・Laboratory Work in Physics ・Practice in Environmental Design3&4Aor4B ・Introduction to Digital Design using Computer Graphics ・Experimental Design Method 1&2 ・Practice in Environmental Design 5&6 ・Exercise in Computer Aided Design of Archi- ・Exercise in Compuer Aided Design of Products ・Surveying ・Field Practice in Surveying ・Building Structural Mechanics1&2 ・Building Materials ・Experimental Methods in Building Structural tecture ・Building Law ・Internship ・Livelihood Instrument ・Building Production ・Dynamics of Structures Mechanics ・Architectural Environmental Engineering1&2 Architecutural environment & equipment ・Reinforced Concrete Structures ・Steel Structures ・Construction Method of Buildings ・Architectural and Urban Equipment1&2 ・Exercise in Architectural Environment and ・Human Environmental Engineering Equipment ・Laboratory Work in Architectural Environmental Engineering ・Environmantal Psychology ・Building Systems ・History of City and Houses ・Planning of Interior Space ・Living Environment and Waste Management ・Urban and Housing Management ・Architecture and Interior Design ・Building Disaster Prevention and Safety ・Architectural Planning and Design ・Urban and Regional Planning ・Living Life and Housing Problem ・House Planning and Design ・History of Western Architecture ・Color for Design and Science Planning &Design ・History of Modern Architecture Planning ・Regional and Urban Cultural Studies ・History of Japanese Architecture ・Housing Environmental Management ・Human Right for Adequate Housing ・Living Environment and Social Research Methods ・Landscape Design ・Landscape Ecology ・Ergonomics ・Esthetics in Everyday-Life ・Outline of Apparel Science ・Nature and Human Design ・Interior Landscape Design ・History of Modern Design ・Theory of Product Design ・Garden Design ・System for Open Space ・Cultural History of Clothing ・Apparel Design and Dressmaking ・Accessible Design ・Web Design ・Graphic Design ・Design for Applied Fine Arts ・Reading Scientific Papers 2 Landscape design ・Seminar in Major Subject ・Research in Major Subject Table 2: Timetable of the Workshop 2009 1 Fri 2 Sat 3 4 5 6 7 Sun Mon Tue Wed Thu 8 Fri 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu May Fri Sat Sun Kick-off Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Considering possibility Jun. Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Collectin data Esquisse Drawing Design methods of connections Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Drawing Jul. Fri Scale model Design methods of connections Sat Sun Mon Tue Wed Thu Sun Mon Tue Wed Thu Fri Structural Design Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Scale model Aug. Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Estimating timber volume Sep. Thu Fri Sat Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Fabrication of members Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Tue Wed Thu Fri Assemble units Oct. Sun Mon Tue Wed Thu Nov. Meeting Fri Sat Sun Mon Tue Wed Thu Assemble units Fri Sat Sun Mon Tue Wed Thu Construction Fri Finish Sat Sun Mon Tue Wed Thu Fri Sat Sun Mon Sat 3. 4. Japan. But timber is one of the most popular material in building houses. So students fabricated timbers to members by themselves. Structural design: The way to estimate stiffness and strength of timber to timber joints is most important in a structural design of timber structures. Some joints on the structure which was designed in this workshop were semi rigid joints with Japanese traditional joints like dowels and wedges. And these joints was evaluated by both experimental and analytical method. Management a schedule: Processes of work have to manage properly, especially on business. Figure 1: Developed figure of a soccur ball To achive these topics, a time table, which was shown in Table 2, was configured. The kick-off meeting was held on 29th May 2009. In this meeting, the goal of this workshop, which was building a timber structure by their hands and learning how to architect, was shown. 3.3 CONCEPT AND DESIGN There are many traditional timber structures around students of KPU. Therefore first concept was applying Japanese traditional technique and timber engineering. One technique was an ARARE-joint. Each member had a comb shape at both ends and put to other member like a finger joint. Another was a KOMISEN-dowel. This was a one of a cotter pin and usually 15-18mm square timber.Second conecpt was designing from an instability looking model like a sphere. Instability of looking led us to rising tension but an actual structure was naturally stable. A soccur ball made with timber was decided based on these concepts. Soccur ball consisted of 20 hexagonal shapes and 12 pentagonal shapes. When either of them were constructed, others were shaped automatically. And hexagonal shape was easier than pentagonal shape because the former consisted of regular triangles. ARARE-joint were used for putting members together hexagonal shape. KOMISENdowels were used for constructing a soccur ball by conecting hexagonal shapes. A developed figure of a soccur ball was shown in Figure 1. Details of connectting each unit was shown in Figure 2. A hexagonal shaped unit (7) had Figure 2: Hexagonal shaped units Figure 3: Members of hexagonal units Figure 4: Disscussion about details of connections 3 boundaries with other hexagonal units. Another 3 sides of this unit made up each side of pentagonal shapes as opening. And this hexagonal shaped unit consisted of two types members. 3 members A (Figure 3) were boundaries with pentagonal openings, another 3 members B (Figure 3) were boudaries with other hexagonal units connectted by KOMISENdowels. These 6 members put together by using ARARE-joints, shown in Figure 5. 3.4 FABRICATION Figure 5: Details about ARARE-joint This was the first time to operate wood processing machines for students. At first profecional operaters taught students some important reminder and methods of operating wood processing machines, shown in Figure 7. Most important reminder was not to touch moving edges. And they needed to operate a machine step by step with precise timing. They could not operate each machine well but mastered soon. 3.5 STRENGTH OF CONNECTION Figure 6: Details about KOMISEN-dowels' connection In order to design for structures, strength of connections were made sure if each connection was enough. In this case, a strength of a connection by KOMISEN-dowels , which was subjected to bending moment, was importat. This was a direction to open hexagonal units. Expeliment by 3 point bending test was shown in Figure 12. It was found out that this connection had an enough strength by reinforceing with the kasugai-clamp which was a Japanese traditional iron. Figure 7: Lecture about the way to operate wood processing machines Figure 10: Pitting holes for KOMISEN-dowel Figure 8: First time of operateing a wood processing machine Figure 11: A hexagonal shape unit Figure 9: Marking on members Figure 12: An expelimrnt for a bending strength of a connection 3.6 ASSEMBLEING AND CONSTRUCTION At first 2 cover parts were constructed by jointing 5 hexagonal units and one middle part by jointing 10 hexagonal units. Each cover part was jointed to a middle part in order of precedence. In fact, one cover part was jointed to a middle part from above. This jointed unit was inverted upside down before other cover part was Figure 13: KOMISEN-dowel jointed. This procedure was shown in Figure 14. Figure 14: Procedure to construct the timber soccer ball Figure 15: A cover part Figure 17: Liftup and moving by humans Figure 16: Construction a middle part with knock in KOMISEN-dowels Figure 18: Fastning polycarbonate panels with screw Figure 19: Detail of ARARE-joints Figure 22: Member of this workshop with the soccer ball Figure 20: A standing student on the soccer ball Figure 23: The accomlished soccer ball 4 CONCLUSION Figure 21: A standing student in the soccer ball It was found that following effects of this workshop; 1. Students found out that an architectural design was worth to work. 2. Some methods of structural design on timber engineering were experienced. 3. They understood that building an actual structure was more difficult than thier images, but this experiment led to stepping up.