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Yona Friedman’s Roofs: manuals for simple, low-cost building
Andrea Bocco1,a, Emiliano Cruz Michelena Valcárcel1,b, Laura Trovato1,c
1DIST-Politecnico di Torino, viale Mattioli 39, 10125 Torino, Italy
aandrea.bocco@polito.it, bemiliano.michelena@polito.it, claura.trovato14@gmail.com
Keywords: Yona Friedman, low-tech, low cost, bamboo construction, learning by doing. Abstract. Since 1973, Yona Friedman, architect, born in Hungary in 1923, used the “manual” as a
method of providing information to those unable to decipher technical drawings. The
communication was entrusted to very schematic drawings, similar to comics, coupled with short
texts. Manuals – mostly produced thanks to the support of UN agencies – were intended to transmit
easy techniques regarding the basics of survival, i.e. shelter and food. The privileged recipients
were slum dwellers.
In his book L’architecture de survie, Friedman explained his lucid vision of an impoverished world,
where in “developing” and industrialized countries alike, conditions of scarcity will be common and
the question of survival will be urgent, even more so in cities. The only effective way to ensure the
survival of the poor would be to support their autonomous development of feasible solutions.
The manuals collected in Roofs contain a number of techniques suitable for people without building
skills. Most involve the use of natural materials and include many different solutions for bamboo
domes, which Eda Schaur and Yona Friedman used in the Museum of Simple Technologies they
built in Madras in 1987.
The techniques – chosen because of ease of use and low cost – have also important ramifications in
terms of autonomy and environmental impact, and are the subject of sometimes advanced research
carried out in rich countries. Therefore they may indicate a possible path towards a socially,
economically and environmentally sustainable architecture.
This presentation covers both the illustration of Roofs and a discussion of its current technological
viability, which the authors conducted in students workshops, building a number of full-scale
prototypes. The possible applications in the improvement of housing in the city and the
metropolitan area of Buenos Aires are covered in paper no. 114.
Introduction
Roofs is a collection of practical information on the building of roofs for the shelters of the poorest
populations. It bears the acronyms UNESCO, CCSK (that is, Friedman’s Centre for the
Communication of Scientific Knowledge), and UNU (United Nations University), and is still freely
downloadable from UNESCO archives. [1] One of the most appreciable peculiarities of Roofs lies
in the simplicity of its drawings and texts, through which Friedman meant to make himself
understood by the larger amount of people, even illiterate.
He had first experimented with this communication strategy in 1973, when he decided to make the
contents of his theoretical text Pour une architecture scientifique [2] – a book conceived in order to
enable the inhabitants in designing their own living environment, a similar engagement to that of
some contemporary authors, such as Habraken and Alexander – available to children. [3]
From that time through most of the Eighties, a large part of Friedman’s work consisted in
composing manuals. The cartoons encouraged self-planning and self-building practices, and innate
creative capacities, with the scope of empowering citizens in fields deeply affecting their lives, but
from which they had been expelled by professionals and political power. Awareness would build up
a convivial relationship between one’s will and the tools to follow it up. [4]
The Manuals
Since 1973, Friedman collaborated with UNESCO on housing insecurity issues in big cities of
developing countries; in 1976 he was a member of the preliminary commission to the first UN
Conference on Habitat, to be held in Vancouver. In 1977, Friedman collected what he had learnt
from such appointments in his fundamental essay, L’architecture de survie (“The architecture of
survival”). [5]
Friedman proposed that the spontaneous initiatives of the poor should be supported, both in housing
and food provision. He also claimed that the best way to learn is from direct experience, what is
denied by formal education. Friedman thought that the cartoon manual would have transmitted
knowledge elements without compelling the reader to use them in a specific way: “Only those from
bottom up are true solutions.” [5:74]
Thanks to successful diffusion initiatives in India, in 1982 the UNU financed the establishment of
CCSK, whose scope was the realisation of information tools for the improvement of living
conditions in developing countries. [6] This included translating scientific knowledge into
information which had to be comprehensible and usable by the poorest. The design of manuals was
by far the largest activity the CCSK undertook.
Architecture was just one of the many topics – they included food (production, storage and
processing), health (diet, hygiene and basic care), water management (collection, conservation,
treatment, irrigation), habitat, ecology, material resources, energy, self-organisation,
communication, business. In all of these CCSK tried to teach simple techniques relying “more on
investment of labour than cash or materials that must be bought.” [6:335]
Only some of the topics were actually covered; anyhow, such ‘Encyclopaedia of survival’ [7:166] is
outstanding in vision and richness, with potentially enormous ramifications: let us only think of
what might be accomplished if a similar initiative were undertook now, in the age of Internet.
The Museum of Simple Technology
Besides the manuals, another means of knowledge diffusion envisaged by the CCSK was the
construction of a Museum of Simple Technology. Friedman conceived it as “a permanent exhibition
of techniques, traditional or modern, implementable by disfavoured people in order to improve their
life. The exhibits consist of artefacts used for or resulting from such techniques, accompanied by a
simple and pragmatic explanation.” [8:1]
He held it was crucial that all exhibits be produced at a very low cost (or, better, without any money
expenditure), make use locally available knowledge, and constitute innovations bringing tangible
improvement to the quality of life. Moreover, they should have been easy to understand and copy.
The target group was the urban poor.
The Museum building itself was supposed to embody building techniques that the slum dwellers
might use to improve their shelters. Therefore materials were selected according to economy and
technical appropriateness – cement and steel were ruled out (“in India, even scrap metal can be too
expensive for the disfavoured”) [6:335] and the use of timber was minimised. Expenditure in labour
was privileged on cash for building materials.
Friedman designed several architectural projects for the Museum. One, which was not
implemented, consisted in a complex of three large rooms covered by ‘ring-ball’ domes: (Fig. 1) a
technology which would allow covering quite large spans without intermediate columns and using a
limited amount of material, that in our opinion was never really tested, although Friedman built a
few prototypes at different stages of his career. [9] [10:62] It seems to us that he can be fully
credited with such technology – which is described in the manual with the same name [1:89-99] –,
as already in 1959 he invented a system of ‘spherical constructions’ based on tangential joints
connecting what he dubbed ‘indeterminate polygons’ (that is, circles). From a single element – a
steel ring –, this system would allow to build various polyhedra, assemblable almost at will, their
faces being in all cases a ring with the same diameter. [11] Translating this system in ‘low-tech’ he
substituted bamboo for steel, and reduced the diameter of the rings; he even proposed that these be
prefabricated handicrafts, so to obtain a low-cost building component made from local material.
[10:62-64] Theoretically, rings could be the only load-bearing element in indefinite space chains: in
practice though, either they are so large that they contain a full storey, or they can be used for roof
structures only – which will be quite cumbersome, and will require a different vertical structure.
Fig. 1 Friedman’s sketch of an auditorium for Madras Museum, to be covered by a ring-ball roof.
Fig. 2 Some pavilions of the freshly-completed Museum of Simple Technologies, 1987.
This technology is quite different from that of the built Museum, which was erected in 1987 at the
campus of Anna University, in Chennai (Madras). Eda Schaur’s and Yona Friedman’s project
consisted of 13 square modules – 6 pavilions enclosed by walls and 7 covered courtyards. (Fig. 2)
Walls were rather ordinary self-bearing raw and fired brick masonry, while roofs were bizarre
double-domed structures, spanning 4.3 m, built of 10 cm diameter bamboo culms that had been split
in eight strips, or 2.5 cm diameter whole canes. Domes were supported by an independent structure
made of timber posts inserted in concrete pad foundations, and tightly tied to the domes’ base
frames with vegetal rope. The technology of these domes is described in the manual Bamboo domes
with suspended mat cover, [1:51-70] one of the very few containing also technical drawings. The
upper dome is the load-bearing one, while the bottom one hangs from it and carries the roofing.
The latter is relatively flat, which allows to keep down its surface area (just a bit more than with a
flat roof, as opposed to common domes), and to employ sheets and mats for roofing. Friedman was
proud of an innovation he dubbed ‘alumats’: an aluminium sheet 0.05 mm thick glued to a bamboo
mat locally handcrafted – or a sandwich made of two outer mats and an aluminium sheet in
between. Such an easy-to-use building product – coupling of a widely-spread, low-cost traditional
technique with an also low-cost product issued from advanced industrial manufacture – is a good
example of CCSK’s scientific and socioeconomic goal. ‘Alumats’ offered new performances –
watertightness, heat reflection – for a flexible, lightweight building product, alternative to
corrugated sheets.
Upper domes supported shading screens – in the photos, one of the most appealing features of the
Museum –: substantially, they were flat baskets, reducing solar irradiation on the ‘alumat’ roofing.
Domes were built of long and very thin elements, easily obtainable anywhere, although not valued
anymore for building purposes, in spite of their long tradition – especially in the region. The
coupling of advanced scientific knowledge – e.g. on grid shells [12] – with traditional know-how –
e.g. in tying rope joints – allowed Schaur and Friedman to propose a strong and lightweight roof
structure, made with a minimum amount of material, and not asking for a high degree of precision
from the builders.
The Museum was built by basketmakers lacking previous experience in building, who lived in
slums nearby. In 1988 ten more modules were scheduled, but the project was never completed.
Indeed, the Museum was soon dismantled; overall, it did not operate for more than two years. Also
the ambitious program of building a network of museums stayed just a charitable intention of
Friedman’s. [13:21]
Roofs
Roofs was probably assembled around 1991. (Fig. 3) It contains 29, mostly previously-released
manuals and provides useful information for the building of low-cost roofs. Friedman thought
technical innovation of roofs was an important mission: slum dwellers, although inexperienced in
building, might not need assistance for erecting walls, while it would have been relevant to advise
them so to substantially improve the roofs of their shelters. He observed that this part is the most
difficult for the self-help builder, and therefore the most unsatisfactory both structurally and in
terms of liveability – e.g. heat and noise problems due to corrugated sheets; rain leakage...
These manuals constituted a remarkable case of popularisation of ‘low tech,’ and a core of a
possible future encyclopaedia of building with natural materials, including ecological and low-cost
solutions. (It is somehow peculiar that low-cost and ‘outdated’ building techniques – in that not
based on reinforced concrete – are closer to what should today be considered as sustainable than
their industrialised, post-WWII counterparts). Friedman was moved by a humanitarian and
environmental urgency. He affirmed that “the society of poor world is inventing the architecture of
survival.” [5:13]
But, notwithstanding its wide scope, Roofs was not a complete design and/or building handbook,
like van Lengen’s. [14] Friedman wanted to provide convivial tools to develop people’s skills and
knowledge, and give them some agency, [15] more than giving them technical solutions.
With today’s eyes, one cannot restrain from observing that scientifically grounded and habitat-
improving innovations – be they exuberant grid shell domes, or appropriate technology applied to
local materials – proposed by engaged technicians have often be rejected, because for slum-dwellers
it is more crucial that their house resembles to the mainstream model than it performs well in terms
of structural safety, comfort, usability, and even cost.
Fig. 3 The first two pages of the manual Bamboo domes with suspended mat cover.
Fig. 4 A prototype built under Schaur’s direction, at the Ahmedabad School of Architecture.
Eda Schaur’s and IL’s Contribution to Research on Bamboo Building
Eda Schaur, CCSK’s deputy director, was at the same time a fellow researcher at the Institut für
Leichte Flächentragwerke (IL) where she worked, among other things, on surface structures
(shells). A relevant part of the IL’s work was dedicated to the possible employment of lightweight
structures in developing countries. (It must also be reminded that a few years before Gernot Minke
– still one of the most prominent experimenters and propagators of technologies based on natural
materials – was too a fellow researcher at the IL.)
The IL published one of the first books in which bamboo as a building material is examined
thoroughly. [16] Its outstanding structural properties could only stimulate an inquisitive mind as
Frei Otto’s, who held that research on bamboo structures was useful to understand the behaviour of
vegetal thin rods, which could be employed even in large-span structures such as the Mannheim’s
Multihall he designed. But, besides these advanced usages, the IL hoped that appropriate
technology research on bamboo would stimulate a humane construction exploiting locally available
resources – craft traditions included. [16:394] The goal was to understand how to minimise the use
of material and obtain strong – even earthquake proof – structures with very thin elements.
Wickerwork creates flexible and strong objects.
The IL, as many other subjects wishing to promote an architecture truly adapted to human beings
and the environment, had a sincere interest for traditional buildings. In fact, they noted that bent
rods, subject to compression, can be found in many primitive cultures, and that baskets – an almost
universal artefact – can be enlarged to become building structures. [16:304] Economic and
ecological reasons are therefore found both in out-of-the-ordinary engineered grid shells and in
many vernacular shelters, both temporary and permanent, such as the Tuareg tent of Southern Aïr,
[17:12] mongulu huts of Baka Pygmies, and Dorse houses of southern Ethiopia.
In our opinion, the bamboo dome building techniques described in Roofs are mostly the result of
IL’s and Schaur’s research, while ‘ring ball’ constructions derive from Friedman’s research on the
industrialisation of the building trade, as discussed above. During her appointment at the
Ahmedabad School of Architecture, Schaur performed research on split bamboo structures, mainly
grid shells. [16:330] She chose to work with split bamboo as opposed to whole canes, as the first
can be bent easily, while the second need to have a small diameter, and to be green or duly
prepared. (Fig. 4) Tests showed that the introduction of a secondary diagonal grid notably increased
strength – as we have verified. Schaur tested also that traditional basket weaving techniques in view
of their employment for building. A model built with thin bamboo strips by a skilled basket-weaver
stood a 1000 N/m2 distributed load without significant deformation. This made her conclude that a
full-scale construction would be remarkably strong. [16:336]
Our experience
To conclude, we take the liberty of introducing a few observations deriving from our experience, as
in the last two years we have built in five occasions reproductions and rearrangements of Schaur
and Friedman’s bamboo structures, together with students and volunteers. Among these occasions,
at Buenos Aires Bienal de arquitectura (2013) we realised a small exhibition where a split bamboo
dome and a smaller-than-life, demonstration ring-ball construction were shown (both were built by
UBA students); (Fig. 5) and as part of the Architectural Construction Studio (Politecnico di Torino,
School of Architecture), students built in 2014 eighteen different models taken from Roofs and in
2015 eight split bamboo domes and two ring-ball constructions. (Fig. 6) The self-building workshop
Construir con el delta held in Tigre (province of Buenos Aires) in 2014, directed by Emiliano
Michelena, is described here in paper no. 114.
One main reason for most of these experiences was to verify the buildability of the Roofs, or, more
precisely, to check the comprehensibility of the instructions by people lacking building skills. In
fact, we had noticed that Friedman’s manuals contain little explanation on how to obtain several
details, such as joints, knots and cane cuts, on care to be taken because of the material’s
characteristics (e.g., the opportunity to cut and make joints close to bamboo nodes, or special
recommendations regarding its very small shear strength), or on the tools to employ. As one
student, Tom Dagan, noticed, “Friedman’s manuals are more conceptual than practical, and some
basic understanding of (or experience in) DIY is needed.”
Fig. 5 The installation at the Bienal de arquitectura in Buenos Aires. Fig. 6 Students working at
2015 workshop, PAV, Torino. Fig. 7 A few examples of joints using rope and bamboo pins.
Friedman drew his manuals for very poor and badly housed people, but nevertheless used to help
themselves to solve their survival problems, and therefore skilled in some trades (maybe including
some relative to bamboo); his scope was to give them information regarding new techniques which
would have enriched their know-how. This is probably the reason why he was not concerned with
how to implement building details, as he left the choice to self-builders according to available, or
culturally appropriate, techniques and materials. But this was not the case with our students and
volunteers!
Generally speaking, each of the students groups was asked to build a 3x3 m prototype starting from
a square framework braced at the corners (in the case of bamboo domes) or a 6 m diameter one
using 1 m diameter rings (in the case of ring-ball constructions). For joints we gave preference to
rope and wire – to obtain reversible joints, and because these products had been indicated by
Friedman. [1:100-105] (Fig. 7) Canes were not treated, but in 2015 we were gifted high-quality,
well-seasoned Phyllostachys pubescens canes. Out of these experiences we obtained some
qualitative knowledge:
as largely expected, to control the geometry of a bamboo construction is not obvious, be it
made with whole or split canes, as the thickness of the walls is not uniform, and the canes
themselves are tapered. Experience suggests ways to fit, but a certain degree of asymmetry
must be accepted. (Fig. 8) The same problem occurs with ring-balls: rings are not perfect
circles, as to the above-mentioned facts the higher stiffness of the overlapping segment is
added. (Fig. 9) Diaphragm parts need to be removed in order to regularise the element’s
behaviour and facilitate bending.
some domes tend to settle down. (Fig. 10) Forms designed by Schaur and Friedman do not
escape gravity, even though being made of extremely light elements, which are also very
elastic. The question was studied in form-finding experiments on cyclic knots, particularly by
Dmitri Kozlov. [18] Both configurations result in self-supporting structures subjected to
tension, like big springs.
Fig. 8 A dome prototype built from Roofs (page 60, left). Fig. 9 A dodecahedron to be used as one
of the components of a ring-ball structure. Fig. 10 A ‘petal’ dome prototype built from Roofs (page
131). Fig. 11 A double dome prototype built from Roofs (page 60, right).
as it was easy to expect, it was shown that some know-how in binding is much called for.
Tying points, particularly those fastening strips upon themselves to form rings, act as ‘fuses,’
so that not a single ring broke when a storm knocked down some constructions of 2015
workshop. (But those most affected by the impact with the ground were permanently
deformed). The event also showed the easiness of repair of these constructions, as Friedman
claimed.
domes with strips radially crossing at the top or with a ring acting as an oculus are stiffer than
those whose design leaves a void at the top. Also, domed roofs (central symmetry) appeared
more stable and thus generally more durable than vaulted ones (axial symmetry), because they
are connected to the base framework on four sides, not just two.
some manuals propose a double roof: an upper load bearing roof, and a bottom sheltering
roof, which supports a waterproof membrane, and/or a shading screen. In our experience
though, the latter actually stiffened the whole structure, increasing its structural performance.
(Fig. 11)
Friedman’s basic assumption that particular attention should be dedicated to the improvement
of roofs, as they are the most delicate part of a building, is certainly true, but the correct
execution of the vertical supports of bamboo roofs is not negligible nor obvious. The
foundation ought to be stiff enough and direct contact of bamboo (or timber) poles with the
ground should be avoided; the column must be able to resist horizontal load, possibly with the
help of bracing elements; knots connecting posts and the dome base framework must be
correctly placed, strong but elastic, and able to transfer vertical stress. We found that it is
preferable to build bundle columns made of two or three culms rather than a single one, albeit
with a larger diameter. However, in the occasion of the collapse of our 2015 workshop
structures we noticed that the weak point was the joint between columns and ground, not the
stiffness on vertical planes nor the joints connecting posts and dome framework. It was not by
chance that in Madras Museum the vertical supports were inserted in a small pad foundation;
while in 1985 prototypes the structure had been reinforced adding horizontal rods at the base,
lying on the ground, and diagonal braces in some of the vertical planes.
in ring-ball constructions it is not easy to select the most appropriate points to tie the columns
and the roof together: Friedman affirmed that these are “in spots where several rings meet
and, if possible, where their tangent is near to vertical.” [1:93] In our experience, the first
condition is essential; but often contrasts with the second: in other words, we could not place
the posts on the rings’ tangent – only at an angle. Giving a saddle shape to the column’s end,
where the connection of several rings was inserted, and binding with rope produced a fairly
stiff joint. However, this solution – as it is punctiform compared to the extension of the roof,
whose elements are all to be considered as load-bearing structure at the same extent –
inevitably implies a measurable, yet not really detectable deformation of the construction.
(Fig. 12)
Fig. 12 A ring-ball structure consisting of six-and-a-half dodecahedra and twelve tetrahedra
(adapted from Roofs, page 98).
some constructions appeared more durable than others. For instance, the dome made of
intertwined circular ‘petals’ [1:127-132] performed well (after more than one year it is almost
intact) because it has tangential joints (split bamboos are tied to the canes constituting the
base framework, and not perpendicular to them – a position which often leads to cut slits into
them). (Fig. 10) Moreover, not piercing the canes allows to possibly reuse them when the
structure is disassembled. We noticed an easy onset of rot whenever water stagnation in
internodes occurred, albeit for a few days. Therefore we think it is crucial to avoid exposed
inflow points by design, and if possible to avoid piercing the canes at all.
the usability of the space covered by both kind of roofs is a relevant issue. Often, domes based
on a square actually cover a smaller area as they stem from the middle section of the sides and
the corner braces, leaving the corners unprotected: to avoid so, a different configuration
should be worked out. On the other hand, ring-ball constructions cover a much larger area but
the unencumbered space, free from vertical supports, is more or less the same than that
obtained with the square domes.
Future Work
Our experience with Friedman and Schaur’s bamboo roofs is less than extensive. Our experiments
led to more questions than answers, and we plan to develop further research on this kind of
constructions. To begin with, we want to measure quantitatively the phenomena occurring,
something that in the haste (and excitement) of the workshops was not easy to perform – we don’t
even have an exact figure for the weight of our roofs. Moreover, we would like to extend our
experience building more, and more focussed, constructions. To mention just a few of our
intentions: load tests on prototypes; comparison of durability and buildability of different joint
shapes and materials; larger dimension ring-ball constructions; comparison – in terms of strength
and durability – of split bamboo with very small diameter green bamboo; checking what happens
(also in terms of wind load) if waterproofing sheet and/or shading screens are added to the roofs
skeletons.
Acknowledgements
First of all, we wish to thank Eda Schaur, who was so generous to accord us a one-day-long
interview, without which we would not have understood many facts regarding Roofs.
We acknowledge the massive technical support obtained from Angela Lacirignola, in charge of the
DAD-STI laboratory at our university.
Laboratori di Barriera and Parco di Arte Vivente (PAV) need to be credited for having kindly
hosted our students workshops, respectively in 2014 and 2015.
The bamboo employed in the 2015 workshop was granted by the grower Walter Montiglio, through
Roberto Pichetto, who is working to establish a bamboo production chain in Piedmont.
Last but not least, we are grateful to our publisher Quodlibet, as this paper much owes to the
forthcoming publication of the Italian edition of Roofs.
References [1] CCSK, Roofs, vol. 1-2, Paris : UNESCO, [1991]. 1st volume:
http://unesdoc.unesco.org/images/0008/000876/087695eb.pdf; 2nd volume:
http://unesdoc.unesco.org/images/0009/000908/090863eb.pdf.
[2] Y. Friedman, Pour une architecture scientifique, Pierre Belfond, Paris, 1971.
[3] Y. Friedman, Comment vivre entre les autres sans être chef et sans être esclave?, 1973.
[4] I. Illich, Tools for conviviality, Harper and Row, New York, 1973.
[5] Y. Friedman, L’architecture de survie, Éditions de l’Éclat, Paris, 1978.
[6] Y. Friedman, Centre of scientific knowledge for self-reliance, Leonardo, 4 (1986) 333-336.
[7] Y. Friedman, Utopies réalisables, Éditions de l’Éclat, Paris, 1974.
[8] CCSK, A Museum of Simple Technology, 1981.
[9] Y. Friedman, M. Homiridis, Drawings and models, Les presses du réel, Dijon, 2010,. pp. 380-
381.
[10] Y. Friedman, E. Schaur, Architetture per la gente, Spazio e Società, 50 (1992) 57-64.
[11] Y. Friedman, L’industrialisation et la ville, Techniques et Architecture, 25 (1964) 176-177.
[12] F. Otto et al. (Eds.), IL10 Gitterschalen/Grid Shells, Institut für leichte Flächentragwerke,
Stuttgart, 1974.
[13] Y. Friedman, E. Schaur, Uno strumento di crescita, Spazio e Società, 40 (1987) 86-93.
[14] J. van Lengen, The barefoot architect. A Handbook for Green Building, Shelter Publications,
Bolinas, 2007.
[15] N. Awan; T. Schneider; J. Till, Spatial Agency. Other Ways of Doing Architecture, Routledge,
London, 2011.
[16] S. Gaß; H. Drüsedau; J. Hennicke (Eds.), IL31 Bambus/Bamboo, Institut für leichte
Flächentragwerke, Stuttgart, 1985.
[17] L. Kahn (Ed.), Shelter, Bolinas : Shelter Publications, 1973.
[18] D. Kozlov, Form-Finding Experiments with Resilient Cyclic Knots, in: G. Hart, R. Sarhangi
(Eds.), Bridges 2013: Mathematics, Music, Art, Architecture, Culture (conference proceedings), pp.
419-422.
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