1. INTRODUCTION
⌅1.1. General
⌅The
built cultural heritage is generally agreed to constitute a material
element whose historic, documentary and aesthetic information merits
preservation for future generations. Concrete heritage is the latest to
be added to the list of materials, although not without some controversy
(11.
Heinemann, H.A.; van Hees, R.P.J.; Nijland, T.G. (2008) Concrete: Too
young for conservation? In: D’Ayala & Fodde (Eds), Structural
Analysis of Historic Construction (pp. 10). London: Taylor & Francis
Group.
). Its maintenance and conservation are not priority issues (22.
Ramírez Guerrero, G.; Arcila Garrido, M.; Chica Ruiz, A.; Benítez
López, D. (2019). Concrete as heritage: Social perception and its
valuing - the Zarzuela hippodrome case. WIT Trans. Built. Environ. 191, 17-27. https://doi.org/10.2495/STR190021.
),
for, in the absence of acknowledgement and appreciation, it is not
deemed a tourist attraction. Nonetheless, the cultural significance of a
growing number of concrete buildings is prompting listings as heritage
assets (3-53.
Macdonald, S.; Arato Gonçalves, A.P. (2020). Conservation principles
for concrete of cultural significance. Los Angeles: Getty Conservation
Institute.
4. Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.;
Aranburu, A.; Zabaleta, A.; García-García, F.; Antigüedad, I.;
Morales, T. (2020) Understanding the pioneering techniques in reinforced
concrete: the case of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
5.
Merzoug, W.; Chergui, S.; Zouaoui, M.C. (2020) The impact of reinforced
concrete on the modern-day architectural heritage of Algeria. J. Build. Eng. 30, 101210 https://doi.org/10.1016/j.jobe.2020.101210.
).
Although
as a material concrete can be traced back to the Roman Empire, when
lime- and pozzolan-based hydraulic cement (opus caementicium) was
discovered (66.
Jackson, M.D.; Landis, E.N.; Brune, P.F.; Vitti, M.; Chen, H.; Li, Q.;
Kunz, M., Wenk, H-R.; Monteiro, P.J.M.; Ingraffea, A.R. (2014)
Mechanical resilience and cementitious processes in Imperial Roman
architectural mortar. PNAS. 111 [5], 18484-18489. https://doi.org/10.1073/pnas.1417456111.
),
the standardised production of concrete and its use in new forms of
construction are fruit of the intellectual progress attendant upon the
industrial revolution. In 1824 Joseph Aspdin patented a process for
making portland cement (PC), whilst François Coignet used precast
structural concrete for the first time in 1852 and S.T. Fowler was
granted the first-ever patent for reinforced concrete technology in a
wall built in 1860 (77.
Gross, G. (2018) Concrete heritage conservation and the viability of
migrating corrosion inhibitors, Master´s Thesis, Columbia University. https://doi.org/10.7916/D8DV32P9.
).
French
architects Auguste and Gustave Perret were often contemporarily
credited for pointing the way to the modern use of concrete (77.
Gross, G. (2018) Concrete heritage conservation and the viability of
migrating corrosion inhibitors, Master´s Thesis, Columbia University. https://doi.org/10.7916/D8DV32P9.
).
It was not until the twentieth century, however, that it came to be
regarded as a ‘noble’ material, used by modernist, brutalist and
expressionist architects (55.
Merzoug, W.; Chergui, S.; Zouaoui, M.C. (2020) The impact of reinforced
concrete on the modern-day architectural heritage of Algeria. J. Build. Eng. 30, 101210 https://doi.org/10.1016/j.jobe.2020.101210.
, 88. Frampton, K. (2007) Modern architecture: A critical history, London: Thames & Hudson Ltd, 4th edition.
, 99.
Barberena Fernández, A.M. (2016) Conservación de esculturas de
hormigón: efecto de consolidantes en pastas y morteros de cemento,
Doctoral Thesis, Universidad Complutense de Madrid.
) and sculptors (1010.
Peralbo Cano, R.; Durán Suárez, J.A. (2005) La escultura y la dimensión
del hormigón: morteros y hormigones con aplicaciones
técnico-escultóricas. Granada: Facultad de Bellas Artes (Departamento de
Escultura), Universidad de Granada.
). That drove the international preference for concrete as a material able to modernise construction art (1111. Bergeron, L. (2003) L’impact de la modernisation économique et le patrimoine industriel. Word Heritage papers 5, UNESCO.
). It has since become the predominant construction material (33.
Macdonald, S.; Arato Gonçalves, A.P. (2020). Conservation principles
for concrete of cultural significance. Los Angeles: Getty Conservation
Institute.
, 1212.
de Almeida Valença, J.M.; Fernandes Pereira de Almeida, C.A.; Miranda
Botas, J.L.; Brito Santos Júlio, E.N. (2015) Patch Restoration Method: A
new concept for concrete heritage. Construc. Build. Mat. 101, 643-651. https://doi.org/10.1016/j.conbuildmat.2015.10.055.
).
Historically
emblematic concrete structures and buildings have already begun or will
with time begin to show signs of decay, however (13-1513.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
14.
Berkowski, P.; Dmochowski, G.; Barański, J.; Szołomicki, J. (2018) The
construction history and assessment of two heritage industrial buildings
in Wrocław. MATEC Web of Conferences, 174, 03008. https://doi.org/10.1051/matecconf/201817403008.
15.
Valença, J.; Júlio, E. (2010) Conservation requirements for concrete
heritage. The case study of the buildings of the Fundação Calouste
Gulbenkian in Lisbon. In: P. J. S. Cruz (Ed.), ICSA 2010, Structures and
Architecture, Proceedings of the first international conference on
structures and architecture (pp.439-440). Guimares: CRC Press.
).
Due to the fairly recent advent of this construction material, a full
understanding of its long-term behaviour and durability is still in the
making (33.
Macdonald, S.; Arato Gonçalves, A.P. (2020). Conservation principles
for concrete of cultural significance. Los Angeles: Getty Conservation
Institute.
). It is often in need of repair (1616. ACI PRC-201.2-16 (2016) Guide for Durable Concrete. Detroit, American Concrete Institute.
), subject as it is to decay induced by a number of physical, chemical and biological agents, most commonly carried by water (1313.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
, 1717.
Courard, L.; Guillard, A.; Darimont, A.; Bleus, J.M.; Paquet, P. (2012)
Pathologies of concrete in Saint-Vincent Neo-Byzantine Church and
Pauchot reinforced artificial Stone. Construc. Build. Mat. 34, 201-210. https://doi.org/10.1016/j.conbuildmat.2012.02.070.
, 1818.
Gaudette, P.; Slaton, D. (2007) Preservation Brief 15 : Preservation of
historic concrete. Washington D.C.: National Park Service, Heritage
Preservation Services.
).
Intermediate relative humidity establishes the optimal circumstances for carbonating primarily the Ca(OH)2 (due to its relatively high solubility), but also all the other less soluble cementitious phases (CSH, AFm, AFt) of concrete (1919.
De Weerdt, K.; Plusquellec, G.; Belda Revert, A.; Geiker, M.R.;
Lothenbach, B. (2019). Effect of carbonation on the pore solution of
mortar. Cem. Concr. Res. 118, 38-56. https://doi.org/10.1016/j.cemconres.2019.02.004.
).
In addition, the removal of alkalis (Na, K, Ca) in the leaching
processes modifies the composition of the pore solution and the
stability of the said cementitious phases (2020.
Garcia-Lodeiro, I.; Goracci, G.; Dolado, J.S.; Blanco-Varela, M.T.
(2021). Mineralogical and microstructural alterations in a portland
cement paste after an accelerated decalcification process. Cem. Concr. Res. 140, 106312. https://doi.org/10.1016/j.cemconres.2020.106312
). The concomitant decline in internal pH destroys
the passivity that protects the reinforcement, which corrodes as a
result. If reinforcement corrosion is severe, the oxides clustering
around the rebar may prompt concrete cracking, hastening decay or even
inducing collapse in extreme cases (2121.
Galán, I.; Andrade, C.; Castellote, M. (2012) Thermogravimetrical
analysis for monitoring carbonation of cementitious materials. Uptake of
CO2 and deepening in C-S-H knowledge. J. Therm. Anal. Calorim. 110 [1], 309-319. https://doi.org/10.1007/s10973-012-2466-4.
). In coastal areas or where de-icing salts are used, chloride-induced reinforcement corrosion may also pose problems.
On
occasion, decay may be particularly accentuated in historic concrete
manufactured with high water/cement ratios to enhance workability (11.
Heinemann, H.A.; van Hees, R.P.J.; Nijland, T.G. (2008) Concrete: Too
young for conservation? In: D’Ayala & Fodde (Eds), Structural
Analysis of Historic Construction (pp. 10). London: Taylor & Francis
Group.
, 2222.
Di Mundo, R.; Labianca, C.; Carbone, G.; Notarnicola, M. (2020). Recent
advances in hydrophobic and icephobic surface treatments of concrete. Coatings. 10 [5], 449. https://doi.org/10.3390/coatings10050449.
) or potentially reactive (aggregate-alkali alkali-aggregate reaction; metallic sulphides) local aggregate (1818.
Gaudette, P.; Slaton, D. (2007) Preservation Brief 15 : Preservation of
historic concrete. Washington D.C.: National Park Service, Heritage
Preservation Services.
) due to the absence of regulatory standards (44.
Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.; Aranburu, A.;
Zabaleta, A.; García-García, F.; Antigüedad, I.; Morales, T. (2020)
Understanding the pioneering techniques in reinforced concrete: the case
of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
, 1414.
Berkowski, P.; Dmochowski, G.; Barański, J.; Szołomicki, J. (2018) The
construction history and assessment of two heritage industrial buildings
in Wrocław. MATEC Web of Conferences, 174, 03008. https://doi.org/10.1051/matecconf/201817403008.
) and the knowledge gaps prevailing around decay mechanisms at the time of construction.
Certainly, concrete deteriorates whether it has patrimonial value or not (overloads, cyclical loads, impacts, exposure to extreme temperatures, surface erosion or abrasion, volume changes due to temperature or relative humidity gradients, expansive reactions or exchange, leachate etc.), however, the techniques and materials used in its repair often cannot be the same.
Insufficient understanding of the cause of
decay or of the heritage significance of buildings and structures may
result in inappropriate repair to the detriment of the architectural,
historical and cultural content of the respective monuments (33.
Macdonald, S.; Arato Gonçalves, A.P. (2020). Conservation principles
for concrete of cultural significance. Los Angeles: Getty Conservation
Institute.
, 1313.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
). As a rule, the repair techniques applied, designed for modern concrete (2323.
BS EN 1504-9:2011. Products and systems for the protection and repair
of concrete structures - Definitions, requirements, quality control and
evaluation of conformity - Part 9: General principles for the use of
products and systems. London: BSI.
), are not always
satisfactory for the historic material, either because they are
ineffective or because they fail to honour the principles laid down in
international treaties (ICOMOS Charter of Venice and 2003 Charter (11.
Heinemann, H.A.; van Hees, R.P.J.; Nijland, T.G. (2008) Concrete: Too
young for conservation? In: D’Ayala & Fodde (Eds), Structural
Analysis of Historic Construction (pp. 10). London: Taylor & Francis
Group.
, 1313.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
, 2424.
Pizzigatti, C.; Franzoni, E. (2021) The problem of conservation of XX
century architectural heritage: The fibreglass dome of the woodpecker
dance club in Milano Marittima (Italy). J. Build. Eng. 42, 102476 https://doi.org/10.1016/j.jobe.2021.102476.
)).
That lack of understanding of the efficacy and durability of repair
treatments is one of the challenges posed by heritage concrete
conservation (2525.
Arato Gonçalves, A.P.; Macdonald, S.; Marie-Victoire, E.; Bouichou,
M.; Wood, C. (2019). Performance of patch repairs on historic concrete
structures: a preliminary assessment. MATEC Web of Conferences, 289,
0700. https://doi.org/10.1051/matecconf/201928907001.
)
a field that has only recently begun to come into the spotlight in the
wake of a growing appreciation for modern heritage structures (33.
Macdonald, S.; Arato Gonçalves, A.P. (2020). Conservation principles
for concrete of cultural significance. Los Angeles: Getty Conservation
Institute.
, 1212.
de Almeida Valença, J.M.; Fernandes Pereira de Almeida, C.A.; Miranda
Botas, J.L.; Brito Santos Júlio, E.N. (2015) Patch Restoration Method: A
new concept for concrete heritage. Construc. Build. Mat. 101, 643-651. https://doi.org/10.1016/j.conbuildmat.2015.10.055.
, 1313.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
, 2626. Borg, R.P. (2020) Concrete heritage: challenges in conservation. Symposia Melitensia, 16, 35-52.
). Recent research focuses on the development of specific water-repellent treatments (such as sealers) (2727.
Kapetanaki, K.; Vazgiouraki, E.; Stefanakis, D.; Fotiou, A.; Anyfantis,
G.C.; García-Lodeiro, I.; Blanco-Varela, M.T.; Arabatzis, I.;
Maravelaki, P.N. (2020) TEOS modified with nano-calcium oxalate and PDMS
to protect concrete based cultural heritage buildings. Front. Mater. 7, 1-13. https://doi.org/10.3389/fmats.2020.00016.
, 2828.
Courard, L.; Zhao, Z.; Michel, F. (2021) Influence of hydrophobic
product nature and concentration on carbonation resistance of cultural
heritage concrete buildings. Cem. Concr. Comp. 115, 103860. https://doi.org/10.1016/j.cemconcomp.2020.103860.
) and compatible patch repair mortars (1212.
de Almeida Valença, J.M.; Fernandes Pereira de Almeida, C.A.; Miranda
Botas, J.L.; Brito Santos Júlio, E.N. (2015) Patch Restoration Method: A
new concept for concrete heritage. Construc. Build. Mat. 101, 643-651. https://doi.org/10.1016/j.conbuildmat.2015.10.055.
).
Another
challenge outstanding solution is the heightening of citizen awareness
of the twentieth century’s built heritage, for given the ‘youth’ of the
material involved, the historic-cultural value of that heritage is not
fully acknowledged. Such low appreciation and care raise the risk of
decay (44.
Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.; Aranburu, A.;
Zabaleta, A.; García-García, F.; Antigüedad, I.; Morales, T. (2020)
Understanding the pioneering techniques in reinforced concrete: the case
of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
). Europe’s H2020 project, InnovaConcrete (2929. InnovaConcrete project (2018-2021) Retrieved from https://www.innovaconcrete.eu.
)
was created against that backdrop. One of the project’s main pillars is
the selection and analysis of the 100 most significant concrete
structures built in the 28 EU countries (3030.
DOCOMOMO Iberico, ICOMOS (2019) 100 from the 20th, the InnovaConcrete
selection of the significant 20th Century heritage sites in Europe.
Retrieved from https://www.innovaconcrete.eu/100-from-the-20th-is-online-now/.
)
as outstanding examples of technical, social and aesthetic innovation
in twentieth century architecture and engineering. All those cultural,
historical, aesthetic, social and technological innovation values
provide the significance for their identification as heritage.
Another essential pillar is the development of multi-purpose materials and specific techniques for the conservation of the concrete heritage whose implementation and commercialisation will be validated in laboratories and in the field on seven concrete monuments or singular European heritage structures chosen in keeping with scientific and humanistic criteria.
One of the seven case studies selected, the Eduardo
Torroja Institute for Construction Science headquarters at Madrid,
Spain, representative of interdisciplinary cooperation among twentieth
century architects, engineers and concrete researchers, was chosen for
that reason and on the grounds of the prominence of its founder,
engineer Eduardo Torroja (3131.
Queipo-de-Llano, J.; Pachón-Montaño, A.; García-Lodeiro, I.;
Carmona-Quiroga, P.M.; Blanco-Varela, M.T.; Frías-López, E. (2018)
Singular elements in the architecture of the IETCC: design, execution
and current status. In: Cassinello (Ed.), International Conference on
Construction Research - EDUARDO TORROJA. Architecture, Engineering,
Concrete. Madrid.
). Protected by the city of Madrid
for the singularity of its concrete structures, the building is also
listed in the registry of the modern movement kept by the Iberian
Docomomo Foundation (3232. DOCOMOMO Ibérico. Documentation and conservation of the architecture and urbanism of the modern movement. Retrieved from http://www.docomomoiberico.com.
) and bears the honorary plaque awarded by the Chartered Institution of Madrid Architects’ Bronze Club.
1.2. Historic analysis of the building, an InnovaConcrete case study
⌅Eduardo
Torroja, who played a major role in the scientific, technical and
aesthetic revolution that preceded the rapid development of reinforced
and prestressed concrete in the first half of the twentieth century (3131.
Queipo-de-Llano, J.; Pachón-Montaño, A.; García-Lodeiro, I.;
Carmona-Quiroga, P.M.; Blanco-Varela, M.T.; Frías-López, E. (2018)
Singular elements in the architecture of the IETCC: design, execution
and current status. In: Cassinello (Ed.), International Conference on
Construction Research - EDUARDO TORROJA. Architecture, Engineering,
Concrete. Madrid.
), headed a group of architects and
civil engineers who founded what today goes by the name of Eduardo
Torroja Institute for Construction Science. It was the first institution
in Spain to foster progress in all areas of construction and its
materials (3333.
Equipo Editorial. (1984) Conmemoración del cincuenta aniversario del
Instituto de la Construcción y del Cemento «Eduardo Torroja». Inform. Construc. 36 [365], 5-22. https://doi.org/10.3989/ic.1984.v36.i365.1893.
). Construction of the present headquarters in 1951-1953 (Figure 1a),
with its many precast members and singularly shaped concrete elements,
constituted a genuine workbench at a time when Pier Luigi Nervi was
conducting similar experiments in Italy (3434.
Azorín, V.; Cassinello, P.; Monjo, J. (2012) Archivo Eduardo Torroja.
La Sede del itcc (1949-1953). Inéditos anteproyectos previos a su
construcción. Infor. Constr. 64 [525], 5-18. https://doi.org/10.3989/ic.11.023.
). The main building’s sober and functional lines are based on a single precast 1.60 m tall module (3535. Equipo Editorial. (1958) Costillares. Instituto Técnico de la Construcción y del Cemento. Infor. Constr. 10 [099], 7-26. https://doi.org/10.3989/ic.1958.v10.i099.5575.
) comprising tiled flooring, window and roof gutter (Figure 1b, c and d).
That sobriety and functionality contrast with other more unique
constructional and structural systems, such as the multi-pitched roof
over the coal deposit (Figure 1e),
the retaining wall that encloses the complex while also serving as a
lookout shaded by a unique pergola with rib-like supports (Figure 1f); the pergola in the car park consisting in ‘sidewise-seven’-shaped beam-columns (hereafter, car park pergola) (Figure 1g); and the outdoor chapel (3636. Echegaray, G.; Barbero, M. (1999) Composición arquitectónica. Infor. Constr. 51 [462], 19-42. https://doi.org/10.3989/ic.1999.v51.i462.857.
), a later addition consisting in a likewise rib-like concrete shell (Figure 1h) (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659.
).
). (b) Tile flooring (3939. Eymar, J.M. (1999) Prefabricación. Infor. Constr. 51[462], 43-62. https://doi.org/10.3989/ic.1999.v51.i462.858.
). (c) Window frames (3939. Eymar, J.M. (1999) Prefabricación. Infor. Constr. 51[462], 43-62. https://doi.org/10.3989/ic.1999.v51.i462.858.
). (d) Gargoyle (3939. Eymar, J.M. (1999) Prefabricación. Infor. Constr. 51[462], 43-62. https://doi.org/10.3989/ic.1999.v51.i462.858.
). (e) Dodecahedral coal deposit (4040. Archivo Histórico del Instituto Eduardo Torroja-CSIC. Retrieved from https://www.ietcc.csic.es/wp-content/uploads/2017/02/Archivo_Historico.pdf.
). (f) Pergola with rib-like supports crowning enclosure wall (3838. Nadal, J. (1999) El Instituto Técnico de la Construcción y del Cemento. Infor. Constr. 51 [462], 9-18. https://doi.org/10.3989/ic.1999.v51.i462.
). (g) Car park pergola (3838. Nadal, J. (1999) El Instituto Técnico de la Construcción y del Cemento. Infor. Constr. 51 [462], 9-18. https://doi.org/10.3989/ic.1999.v51.i462.
). (h) Rib-like shell/outdoor chapel (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659.
).
The building is sited in an urban environment on the outskirts of the city, surrounded by woodland and, since the late nineteen seventies, by Madrid’s inner ring road. The weather conditions to which it has primarily been exposed are listed in Table 1. Recent years have witnessed a substantial rise in temperatures, with less rain- and snowfall. Atmospheric CO2, source of concrete carbonation and loss of strength and durability when the material is not duly manufactured, has declined gradually since 2005 (16.18 kt CO2 eq), with today’s values (10.78 kt CO2 eq, 2017) even lower than recorded in 1990.
Weather conditions (4141. AEMET, Agencia Estatal de Meteorología, Spain. Retrieved from http://www.aemet.es/es/serviciosclimaticos/datosclimatologicos/valoresclimatologicos?l=3195&k=28. , 4242. Ayuntamiento de Madrid, Subdirección General de Energía y Cambio Climático (2016) Inventario de emisiones de gases de efecto invernadero del municipio de Madrid. Retrieved from http://www.mambiente.madrid.es/opencms/export/sites/default/calaire/Anexos/InventarioGEI2016.pdf. ) |
|
---|---|
High temperature, July (°C) | 39.5 (1981-2010); 40.7 (2019) |
Low temperature, January (°C) | −7.4 (1981-2010); −1.8 (2019) |
Yearly mean temperature, July (°C) | 25.6 (1981-2010); 28.0 (2019) |
Yearly mean temperature, January (°C) | 6.3 (1991-2010); 6.5 (2019) |
Mean yearly rainfall (mm) | 421.0 (1981-2010); 372.9 (2019) |
Mean yearly number of frost days | 15.7 (1981-2010) |
Mean yearly number of snow days | 3.6 (1981-2010) |
Mean relative humidity (%) | 57.0 (1981-2010) |
Acid rain / other pollutants (4242.
Ayuntamiento de Madrid, Subdirección General de Energía y Cambio
Climático (2016) Inventario de emisiones de gases de efecto invernadero
del municipio de Madrid. Retrieved from http://www.mambiente.madrid.es/opencms/export/sites/default/calaire/Anexos/InventarioGEI2016.pdf. , 4343. Ayuntamiento de Madrid, Dirección General de Sostenibilidad y Control Ambiental (2019) Retrieved from https://transparencia.madrid.es/UnidadesDescentralizadas/Sostenibilidad/CalidadAire/Publicaciones/Memorias_anuales/Ficheros/Memoria_2019.pdf. ) |
|
Mean yearly NO2 (µg/m3) | 31 (mean); 220 (max.) (2019) |
Yearly SO2 (µg/m3) | 9 (mean); 53 (max.) (2019) |
Yearly kt CO2 eq | 12.95 (1990); 16.18 (2005); 10.78 (2017) |
Rain, occasional ice-thaw cycles and vehicle traffic- and heating-induced pollution are the most prominent agents of decay in the building’s concrete structures, some of which were repaired before having rendered 70 years of service.
This study aimed to assess the present
condition of the portland cement concrete (or mortar) structures in this
singular building, a pre-requisite in historic construction
revitalisation (44.
Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.; Aranburu, A.;
Zabaleta, A.; García-García, F.; Antigüedad, I.; Morales, T. (2020)
Understanding the pioneering techniques in reinforced concrete: the case
of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
, 1313.
Heinemann, H. A. (2013) Historic Concrete. From concrete repair to
concrete conservation. Doctoral Thesis, Delft University. https://doi.org/10.4233/uuid:987fafd0-cd76-4230-be0e-be8843cae08e.
).
More specifically, it characterised the pathologies in three
architectural elements that contribute to the building’s unique
identity: the window frames, the car park pergola and the rib-like
concrete shell designed as an outdoor chapel. The necessarily
cross-disciplinary approach (44.
Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.; Aranburu, A.;
Zabaleta, A.; García-García, F.; Antigüedad, I.; Morales, T. (2020)
Understanding the pioneering techniques in reinforced concrete: the case
of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
, 2424.
Pizzigatti, C.; Franzoni, E. (2021) The problem of conservation of XX
century architectural heritage: The fibreglass dome of the woodpecker
dance club in Milano Marittima (Italy). J. Build. Eng. 42, 102476 https://doi.org/10.1016/j.jobe.2021.102476.
) adopted is based on historic and architectural records and the use of non-destructive techniques to collect geophysical data (44.
Damas Mollá, L.; Sagarna Aranburu, M.; Uriarte, J.A.; Aranburu, A.;
Zabaleta, A.; García-García, F.; Antigüedad, I.; Morales, T. (2020)
Understanding the pioneering techniques in reinforced concrete: the case
of Punta Begoña Galleries, Getxo, Spain. Build. Res. Inf. 48, 785-801 https://doi.org/10.1080/09613218.2019.1702498.
, 1212.
de Almeida Valença, J.M.; Fernandes Pereira de Almeida, C.A.; Miranda
Botas, J.L.; Brito Santos Júlio, E.N. (2015) Patch Restoration Method: A
new concept for concrete heritage. Construc. Build. Mat. 101, 643-651. https://doi.org/10.1016/j.conbuildmat.2015.10.055.
, 1414.
Berkowski, P.; Dmochowski, G.; Barański, J.; Szołomicki, J. (2018) The
construction history and assessment of two heritage industrial buildings
in Wrocław. MATEC Web of Conferences, 174, 03008. https://doi.org/10.1051/matecconf/201817403008.
, 1515.
Valença, J.; Júlio, E. (2010) Conservation requirements for concrete
heritage. The case study of the buildings of the Fundação Calouste
Gulbenkian in Lisbon. In: P. J. S. Cruz (Ed.), ICSA 2010, Structures and
Architecture, Proceedings of the first international conference on
structures and architecture (pp.439-440). Guimares: CRC Press.
).
The structures chosen, representative of distinct stages in building
construction (1953 and 1969), were built with different materials
(concretes or mortars) and construction methods (precast or
cast-in-place) and some but not all had been rehabilitated or maintained
prior to the study.
Another purpose of diagnosis is to minimise the maintenance required via periodic inspection of structures and establish conservation strategies that preserve the original conditions as closely as possible. The measures envisaged include validation of innovative preventive treatments compatible with and optimised or developed under the InnovaConcrete project, including consolidants, water-repellents, corrosion inhibitors and micromortars.
In a broader scope, this investigation aims to contribute to the conservation of concrete of the 20th with cultural significance by characterising its pathologies from a preventive conservation perspective and by addressing, where appropriate, preventive conservation solutions (mainly novel protective treatments) which are compatible with established conservation principles in this case of study.
2. METHODOLOGY
⌅The diagnostic campaign began with the study of all the information compiled on the building’s constructional history, including original design drawings and specifications, historic documents on construction methods, materials used, earlier conservation operations and scientific papers.
The working plan drawn up after the aforementioned review and a preliminary visual inspection of the pathologies consisted in characterising the condition of the materials with laboratory physical-chemical tests and field measurements.
2.1 Laboratory characterisation of the concrete
⌅Representative
core samples were drawn from the elements studied for subsequent
laboratory characterisation from low and relatively hidden areas apart
from the window frame, where the sample taken was almost dislodged. The
fine and coarse aggregates were examined under a Nikon Eclipse E600
optical microscope to determine their composition. The former was also
studied with a field emission scanning electron microscope (FESEM)
fitted with a Bruker 20-kV XFlash Detector 5030 energy dispersive X-ray
spectrometer (EDX). Fines size was recorded as measured with the optical
microscope and the medium-sized and large materials as determined with
Image J software based on photographs taken with a standard camera or
Kappa software based on binocular microscopic images. Aggregate sizes
are given further to the d/D nomenclature defined in European standard
BS EN 12620:2003+A1:2009 (4444. BS EN 12620:2003+A1:2009. Aggregates for concrete. London: BSI.
).
A fraction with high cement paste content was obtained from the core samples by mechanically separating as much of the sand and gravel as possible.
The resulting powder was then XRD-scanned with a Bruker D8 Advance 2.2-kW diffractometer (CuK-α1 radiation: 1.5406 Å; CuK-α2 radiation: 1.5444 Å) to identify the hydrated cement phases and detect the possible presence of altered products. KBr pellets bearing concrete or mortar samples were studied with a Nicolet 7600 FT-IR spectrometer (range, 4000-400 cm− 1; 32 scans; spectral resolution, 4 cm− 1) to determine their mineralogical composition. Their portlandite and calcite contents were quantified in platinum crucibles in a N2 atmosphere at 1000 °C and a flow rate of 10 °C/min on a TA SDT Q600 TGC/DSA analyser.
Carbonation
depth was determined by measuring the width of the unstained rim of
fresh fractured surfaces sprayed with thymolphthalein (4545.
BS EN 14630:2007. Products and systems for the protection and repair of
concrete structures - Test methods - Determination of carbonation depth
in hardened concrete by the phenolphthalein method. London: BSI.
)
and sample homogeneity was assessed with a Pundit7 ultrasonic tester by
determining the ultrasonic pulse velocity and respective longitudinal
modulus of elasticity (MOEus) or Young’s modulus.
Standard dissolution procedures (4646.
ASTM C1084-19 (2019) Standard Test Method for Portland-Cement Content
of Hardened Hydraulic-Cement Concrete. West Conshohocken: ASTM
International.
) were used where appropriate to determine the cement:aggregate ratio.
Concrete density and water-accessible porosity were determined as set out in Spanish standard UNE 83980 (4747.
UNE 83980:2014. Durabilidad del hormigón. Métodos de ensayo.
Determinación de la absorción de agua, la densidad y la porosidad
accesible al agua del hormigón. Madrid: AENOR.
).
The
porosity of the window frame mortar was determined with a Micromeritics
Autopore IV 9500 V1.05 Hg intrusion porosimeter. Cylindrical specimens
measuring 40 mm in diameter and approximately 80 mm high were analysed
for compressive strength on an Ibertest Autotest 200/10 test frame as
specified in BS EN 12390-3:2020 (4848. BS EN 12390-3:2020. Testing hardened concrete - Part 3: Compressive strength of test specimens. London: BSI.
).
Dry
and saturated core sample electrical resistivity were measured using
the direct electrochemical impedance spectroscopic (EIS) method (two
external electrodes) (4949. UNE 83988-1:2008. Determinación de la resistividad eléctrica. Parte 1: Método directo (método de referencia). Madrid: AENOR.
).
Readings were recorded on the FRA module of an Autolab 302
potentiostat/galvanostat operating at frequencies of 1 Hz to 1 MHz in
potentiostatic mode with a sine wave amplitude of 350 V. Resistivity was
calculated from the impedance module value at which an imaginary
component was near zero. Concrete core specimens measured 40 mm in
diameter and 49 mm and 43 mm high, respectively for the car park pergola
and for rib-like shell structures.
2.2. In situ non-destructive testing
⌅The
field measurements consisted, firstly, in assessing possible structural
anomalies by comparing the original design drawings for the car park
pergola to the element as it presently stands. That assessment was
informed by the topographic survey data generated by a FARO Technologies
Focus 3D laser scanner (visual field, 305° vertical, 360° horizontal;
range, 0.6 m to 120 m; resolution, 70 pixels) and converted to three
dimensional lattices with FARO Scene 7.1 and Rhinoceros software. The 3D
survey data for the rib-like shell were published in a paper by
Echevarría et al. (5050.
Echevarría, L.; Garnica, C.; Gutiérrez, J. (2014) La costilla laminar
del Instituto de Ciencias de la Construcción Eduardo Torroja
(IETcc-CSIC). Levantamiento mediante láser-escáner y evaluación
estructural. Infor. Constr. 66 [536], e038. https://doi.org/10.3989/ic.14.116.
), whilst none was deemed necessary for the windows, in light of their straightforward geometry.
Reinforcement bar position and the thickness of the concrete cover were determined with a Hilti PS 1000 X-scan ground penetrating radar (GPR).
In-situ
tests were likewise conducted to determine the condition of the
concrete elements. Their surface hardness was measured with a Proceq
DigiSchmidt Schmidt hammer (5151.
BS EN 12504-2:2013. Testing concrete in structures - Part 2:
Non-destructive testing - Determination of rebound number. London: BSI.
) and the respective compressive strength values were calculated from the manufacturer’s calibration curves.
Corrosion
of the steel embedded in the concrete was assessed quanti- and
qualitatively. The electrochemical parameters recorded for that purpose,
all of which called for a ground connection to the steel, included: i)
corrosion potential (Ecorr) (5252.
ASTM C876-15 (2015) Standard test method for corrosion potentials of
uncoated reinforcing steel in Concrete. West Conshohocken: ASTM
International.
); ii) corrosion rate (Icorr) (modulated confinement method (5353.
Polder, R.; Andrade, C.; Elsener, B.; Vennesland, Ø.; Gulikers, J.;
Weidert, R.; Raupach, M. (2000) Test methods for on site measurement of
resistivity of concrete. Mater. Struct. 33, 603-611. https://doi.org/10.1007/BF02480599.
, 5454.
Andrade, C.; Martinez, I. (2005) Calibration by gravimetric losses of
electrochemical corrosion rate measurement using modulated confinement
of the current. Mater. Struct. 38, 833-841. https://doi.org/10.1007/BF02481656.
); and iii) concrete resistivity (ρ) (galvanostatic pulse method (5555.
Polder, R.B. (2001) Test methods for on site measurement of resistivity
of concrete - a RILEM TC-154 technical recommendation. Construc. Build. Mat. 15, 125-131. https://doi.org/10.1016/S0950-0618(00)00061-1.
)). All measurements were logged with a NAV-ECM corrosion rate meter.
Because water drives corrosion, the relative moisture in the elements was characterised. Up to 10 readings were taken with a DCL Metrología laser moisture meter in each area selected for analysis.
3. RESULTS AND DISCUSSION
⌅3.1. Car park pergola
⌅3.1.1. Historical background and present condition
⌅Located in the car park, this outdoor structure comprises 22 ‘sidewise-seven’-like 2.5x5.55x0.17 m (height x length x thickness) supports spanned by wooden shading slats. Both concrete and slats (the latter not conserved) were initially painted white (Figure 2). The structural review was based on the original drawings and information in the general design specifications on the type of concrete and reinforcement used to build the supports (Table 2).
).
Design specifications (4040. Archivo Histórico del Instituto Eduardo Torroja-CSIC. Retrieved from https://www.ietcc.csic.es/wp-content/uploads/2017/02/Archivo_Historico.pdf. , 5757. Centro Experimental de Arquitectura (1948) Pliego general de condiciones varias de la edificación. Título 1, Condiciones generales de índole técnica; aprobado por el Consejo Superior de los Colegios de Arquitectos; adoptado en las Obras de la Dirección General de Arquitectura. Madrid. , 5858. Peña Boeuf, A. (1944) ORDEN de 20 de marzo de1944 por la que se aprueba la Instrucción definitiva para el proyecto de ejecución de obras de hormigón. Boletín Oficial del Estado, nº. 153, 4299-4318. ) |
Findings in this study | Eurocode (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI. ) |
|
---|---|---|---|
Compressive strength (MPa) | 17.16 | 30 | 30 |
Water-accessible porosity (v/v %) | ≤5 % to 6 % (concrete wt) | 9.8 | 7 - 24 |
Density (g/cm3) | 2.3 | 2.4 - 2.9 | |
Cement content (kg/m3) | 300-350 | >300 | |
Type of cement | Portland or alumina | Grey portland | |
Gravel aggregate | 800 L/m3 to 900 L/m3 natural or crushed aggregate | Natural aggregate: carbonates, quartz polycrystalline | |
Sand aggregate | 400 L/m3 to 500 L/m3 siliceous sand | siliceous sand: quartz, potassium feldspar, plagioclase, schist | |
Moisture (%) | 30.01 % to 43.6 % | ||
Ultrasound velocity (m/s) | 4471 | ||
Young’s mod. (GPa) | 41.4 | ||
Dry resistivity (kΩ·cm) | 145.38 | ||
Saturated resistivity (kΩ·cm) | 8.45 | ||
Reinforcement bar cover (mm) | > 30 | 0-30 (mostly 10-25) | 35 |
Carbonation depth (mm) | 9 ± 3 |
Surface spalling on the concrete members was patch-repaired in 2007 when the white paint, biological colonies, rust from the exposed reinforcement and poorly bonded grout were sand-blasted off the supports. An epoxy resin passive seal (Legaran by Degussa) was subsequently applied to protect the exposed steel rebar and ensure the bond (with hydraulic binders and resins (Degussa PCC-20)) to the patch mortar used to restore the detached cover. All the surfaces were then painted with Masterseal 325E, a white anti-carbonation coating to detain reinforcement corrosion.
The present visual inspection (Figure 3) revealed concrete cracking at the top and especially at the tip (Figure 3 (b) ) of the supports, material loss, biological colonisation and corrosion in the exposed rebar.
3.1.2. Concrete characterisation
⌅The pergola concrete was characterised to identify the possible origin of the damage and any necessary repairs to choose compatible materials or treatments.
The most prominent physical properties defined in the original design (4040. Archivo Histórico del Instituto Eduardo Torroja-CSIC. Retrieved from https://www.ietcc.csic.es/wp-content/uploads/2017/02/Archivo_Historico.pdf.
, 5757.
Centro Experimental de Arquitectura (1948) Pliego general de
condiciones varias de la edificación. Título 1, Condiciones generales de
índole técnica; aprobado por el Consejo Superior de los Colegios de
Arquitectos; adoptado en las Obras de la Dirección General de
Arquitectura. Madrid.
) and the ones determined from the core samples in this study are given in Table 2, along with other provisions on concrete set out in the Eurocode (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI.
) for new structures exposed to similar environmental conditions.
Aggregate
size distribution was determined by analysing the macroscopic (with no
or low enlargement) and (optical and electronic) microscopic images of
the core samples (Figure 4),
which also revealed their composition, found to be: in the gravel
(d/D=2.5/28), carbonate (micritic texture) and polycrystalline quartz
grains (with and without mica and iron oxides); in the sand
(d/D=0.05/2.5), primarily monocrystalline quartz, and secondarily
metamorphic rock fragments (schist), potassium feldspar (microcline) and
plagioclase (albite). Both size and composition were largely in
agreement with the design specifications (5757.
Centro Experimental de Arquitectura (1948) Pliego general de
condiciones varias de la edificación. Título 1, Condiciones generales de
índole técnica; aprobado por el Consejo Superior de los Colegios de
Arquitectos; adoptado en las Obras de la Dirección General de
Arquitectura. Madrid.
), which called for 800 L/m3 to 900 L/m3 of natural or crushed gravel with up to 3 % clay and 400 L/m3 to 500 L/m3 of rinsed siliceous sand with a maximum size of 38 mm and no more than
10 % clay of a maximum size of 5 mm (50 % coarse grain from 2 mm to 5 mm
and up to 15 % medium grain, from 0.5 mm to 2 mm).
The mixed
(siliceous and calcareous) composition of the aggregates ruled out the
use of both the standard procedure for determining cement content (4646.
ASTM C1084-19 (2019) Standard Test Method for Portland-Cement Content
of Hardened Hydraulic-Cement Concrete. West Conshohocken: ASTM
International.
) based on the HCl-solubility of silica
at 5 °C and the calcium oxide sub-procedure. The design specified a
cement content of 300 kg/m3 to 350 kg/m3.
The
XRD pattern for the high cement content paste contained reflections for
the two primary hydrated phases, ettringite and portlandite, along with
signals for gypsum, perhaps attributable to the deposition of
atmospheric SO2 (5959. Martínez-Ramírez, S.; Zamarad, A.; Thompson, G.E.; Moore, B. (2002) Organic and inorganic concrete under SO2 pollutant exposure. Build. Environ. 37, 933-937. https://doi.org/10.1016/S0360-1323(01)00065-8.
). The most intense lines identified the quartz, calcite, feldspars, albite and microcline present in the aggregates (Figure 5a).
The signals for calcite might also have been generated as a result of
cement paste carbonation. Further to the DTA/TG study, this hydrated
cement-high sample contained 22 wt% calcite and 5 wt% portlandite,
denoting the persistence of a store of alkalinity available for
reinforcement passivation (6060.
Bautista, A.; Velasco, F.; Torres-Carrasco, M. (2019) Influence of the
alkaline reserve of chloride-contaminated mortars on the 6-year
corrosion behavior of corrugated UNS S32304 and S32001 stainless steels. Metals. 9, 686. https://doi.org/10.3390/met9060686.
).
The FT-IR spectrum, in turn, exhibited the bands characteristic of the aforementioned mineral phases (Figure 5b): calcite at 1425, 875 and 712 cm-1; silicate vibrations at around 1000 cm-1; the double band characteristic of quartz at 796 cm-1 and 777 cm-1; the bending vibrations typical of the S-O in sulfates at 668 cm-1; and the stretching vibrations generated by the OH groups in portlandite at 3640 cm-1 (6161. Gadsden, J. A. (1975) Infrared spectra of minerals and related inorganic compounds. London: Butterworth Groups.
).
The carbonation front in the sample core was not very deep, despite the high levels of air pollution to which the material has been exposed over the years: mean CO2 penetration was 8.7 mm, with a maximum of 12 mm (Figure 6, Table 2).
The concrete’s water-accessible porosity was a moderate 9.8 % (Table 2) while its density was 2.3 g/cm3 which, like its Young’s modulus, lay within the range defined in Eurocode BS EN 1992-1-1 (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI.
) At 30 MPa its compressive strength, far higher than the design value, was likewise as recommended in (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI.
) for concrete in standard structures.
Core
specimen electrical resistivity, found (prior to mechanical
characterisation) to assess the risk of steel corrosion, was 8.45 kΩ·cm
under saturated and 145.48 kΩ·cm under dry conditions. Further to the
criterion proposed by Polder et al. (5353.
Polder, R.; Andrade, C.; Elsener, B.; Vennesland, Ø.; Gulikers, J.;
Weidert, R.; Raupach, M. (2000) Test methods for on site measurement of
resistivity of concrete. Mater. Struct. 33, 603-611. https://doi.org/10.1007/BF02480599.
)
for saturated conditions, here the reinforcement would be at high risk
of corrosion, given its low resistivity, <10 kΩ·cm. The severity of
that risk is relativised, however, by the structure’s location in an
area where neither humidity nor the presence of chlorides is high. For
fuller information in that regard, in situ measurements were made of
electrical resistivity, corrosion potential and corrosion rate (Ecorr, mV; Icorr, µA/cm2) (see item 3.1.3).
By way of summary, according to the laboratory tests conducted the concrete was in good condition further to its age and location.
3.1.3. In-situ testing
⌅Laser scans were captured of the 22 units comprising the structure (Figure 7 (a)) to compare their present 3D geometries to the original design drawings. The results for rib No. 8 reproduced in Figure 7 (b) (ribs numbered consecutively beginning with the one closest to the
building) showed that the built geometry was nearly identical to the
design, with minor deviations possibly due to stake-out errors or to the
time lapsing since construction. The 8 cm to 15 cm slump at the edge of
the overhang relative to the design and a curved deformation on its
upper side together determined a 0.8 cm to 2 cm difference in mid-span
height. Although the value of the slump appearing initially is unknown,
the curved deformation along the top of the element might hold a clue to
the deflection incurred since it was built (bearing in mind that the
formwork used was flat). That relative deformation is in keeping with
today’s legislative provisions on the construction of cantilevered
structural floors in buildings (6262.
Ministerio de Fomento (2019) Documento Básico de Seguridad Estructural,
DB-SE. Real Decreto 732/2019, de 20 de diciembre, por el que se
modifica el Código Técnico de la Edificación. Boletín Oficial del
Estado, 311, 140488-140674.
). The rest of the slump may be due to rotation in the restrained end, as the overlain geometries (Figure 7 (b))
would appear to indicate, and/or related to flawed workmanship or
levelling during construction. Moreover, the pergola has to bear only
its own weight and no pathologies were observed that would entail
structural risk. The deformation nonetheless generates tensile stress in
the top surface of the overhang that favours the appearance of small or
the enlargement of existing cracks on that surface, the one most
exposed to rainwater. It should consequently be protected to prevent
subsequent pathologies.
The ground-penetrating radar (GPR) findings showed that the concrete cover, at <30 mm (Table 2),
fails to meet both the design specifications, which call for a cover
thickness of >30 mm, and the 35 mm minimum presently laid down in the
Eurocode (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI.
) for class 4 structures (buildings and other common structures) with XC4 exposure (outdoor structures).
The electrical resistivity and corrosion potential measurements were below the threshold values defined for steel de-passivation, indicating negligible corrosion and high levels of steel corrosion resistance at this time (Figure 8). All the corrosion rate readings taken in the on-site inspection were likewise very low, corroborating the results observed for the other parameters (Figure 8). To determine representative values of corrosion it will be necessary to monitor the structure, determining corrosion parameters variation with environmental parameters and concrete saturation degree. So these measurements are informing us about the actual corrosion progress but we have no information about what happened before.
In other words, even where the laboratory-measured saturated resistivity values denoted possible corrosion due to low concrete cover resistivity, such problems are unlikely given the absence of chlorides and scant pore water content.
The moisture meter delivered the same readings (30 % to 44 %) for the horizontal and vertical arms of the car park reinforced concrete units. The first and fourth units, the ones closest to the building (Figure 7) that consequently receive less solar radiation, exhibited around 40 % to 43 % moisture content, compared to the 31 % observed in the more distant, less shaded units.
The approximate uniformity of the
Schmidt hammer test results at around 52±2 (dimensionless units) for the
pergola supports measured was an indication that the surfaces are in
good condition. At 60 MPa, the compressive strength extrapolated from
the calibration curves furnished by the hammer manufacturer based on the
rebound readings was double the value determined on the core samples (Table 2)
and 3.5-fold the design specification. According to earlier studies, in
most cases extrapolation is unreliable because the rebound measurements
vary depending on factors such as surface roughness, moisture content,
carbonation, porosity and measuring facility calibration (6363. Sanchez, K.; Tarranza, N. (2014) Reliability of rebound hammer test in concrete compressive strength estimation. Int. J. Adv. Agric. Environ. Eng. 1, 198-202. Retrieved from https://iicbe.org/upload/2458C1114040.pdf.
, 6464. Malhotra V.M.; Carino, N.J. (2004) Handbook on nondestructive testing of concrete. Boca Raton: CRC Press.
).
3.2. Rib-like Shell
⌅3.2.1. Historical background and present condition
⌅The reinforced concrete rib-like shell (Figure 9),
designed to serve as an outdoor chapel, was built nearly two decades
later than the main building, in 1969. Its constructional details are
described in Cassinello et al. (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659.
).
The 6.5 m high, 10 m long shell is characterised by a complex geometry
defined by a Bernoulli lemniscate in which the 40 cm thick base wanes to
6 cm at the outer edge. It is reinforced with steel bars ranging in
diameter from 12 mm to 20 mm. When the structure was stripped of the
formwork 3 d after casting, the quick set concrete used in its
construction exhibited compressive strength of 19 MPa whilst the tip was
positioned 12 cm below the design height.
).
Unlike
the pergola, this structure was not initially painted. The
form-determined inner surface texture was not modified, whereas the
outer surface was treated with a pneumatic bush-hammer (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659.
). No conservation operations have been undertaken since it was built. In an earlier study Echevarría et al. (5050.
Echevarría, L.; Garnica, C.; Gutiérrez, J. (2014) La costilla laminar
del Instituto de Ciencias de la Construcción Eduardo Torroja
(IETcc-CSIC). Levantamiento mediante láser-escáner y evaluación
estructural. Infor. Constr. 66 [536], e038. https://doi.org/10.3989/ic.14.116.
)
detected local rusting but no surface cracking, crumbling or weathering
nor any other symptom that might denote anomalous structural behaviour.
The damage map drawn on the occasion of this analysis shows corrosion in the areas where the reinforcement is exposed, along with biological colonisation, on the top surface of the shell in particular (Figure 10).
3.2.2. Concrete characterisation
⌅The methodology to determine the key characteristics of the rib-like shell concrete was the same as used for the pergola material.
Two core samples were taken from the rib-like shell, one from the slab and the other from the lower part of the rib (Figure 11), for subsequent mineralogical and physical characterisation. Analysis of the optical micrographs revealed that the mineralogical composition of the gravel differs from design specifications (Table 3), for it comprises not only polycrystalline quartz (with and without muscovite and iron oxides) but biomicrite and sparry calcite. In contrast, the primarily quartz-grain based siliceous composition of the sand, with some K-feldspar and plagioclase, is essentially the same as initially designed. Further to their respective particle size distributions, both aggregates are well-graded, with d/D=2/26.7 in the coarse material and d/D=0.02/4 in the fines.
Design characteristics (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659. ) |
Findings in this study | Eurocode (5656.
BS EN 1992-1-1:2013/A1:2015. Eurocode 2 Design of concrete structures.
Part 1-1 General rules and rules for buildings. London: BSI. ) |
|
---|---|---|---|
Compressive strength (MPa) | 19.61 (3 days) | 33.3 | 30 |
Water-accessible porosity (v/v %) | 6 | 7 - 24 | |
Density (g/cm3) | 2.4 | 2.4 - 2.9 | |
Type of cement | Rezola white cement | White cement | |
Gravel aggregate | Siliceous river gravel | Siliceous and calcareous aggregate | |
Sand aggregate | Quartz sand | Quartz sand with potassium feldspar and plagioclase | |
Moisture (%) | 26.4-39.3 | ||
Ultrasound velocity (m/s) | 4363 | ||
MOEus (GPa) | 41.1 | ||
Dry resistivity (kΩ·cm) | 447.29 | ||
Saturated resistivity (kΩ·cm) | 20.97 | ||
Reinforcement bar cover (mm) | Variable from 10 (outer edge) to 40 (base) | <30 (base) | 35 |
Carbonation depth (mm) | 2.6 ± 0.8 |
The most intense reflections observed in the XRD pattern for the high cement paste content fraction were generated by the quartz and calcite aggregates (which had not separated from the paste altogether), although the line attributed to calcite might also be indicative of cement paste carbonation. XRD also detected the presence of gypsum and portlandite, with the latter, according to the DTA-TG findings, accounting for 5.3 wt% and calcite for 20.8 wt% of the total. Those results were corroborated by FT-IR analysis, for the bands characteristic of those minerals were visible on the spectrum.
Compressive strength at 33.3 MPa and Young’s modulus at 41.1 GPa were similar to the values expected of healthy concrete and similar as well to the findings observed for the pergola. Corrosion resistance, at dry (447.29 kΩ·cm) and saturated (20.07 kΩ·cm) electrical resistivity values, was higher in the shell than in the pergola and the carbonation front shallower (mean 2.6 mm, maximum 4.1 mm; Figure 12), due largely to its lower porosity (6 %).
3.2.3. In-situ testing
⌅In earlier inspection, Echevarría et al. (5050.
Echevarría, L.; Garnica, C.; Gutiérrez, J. (2014) La costilla laminar
del Instituto de Ciencias de la Construcción Eduardo Torroja
(IETcc-CSIC). Levantamiento mediante láser-escáner y evaluación
estructural. Infor. Constr. 66 [536], e038. https://doi.org/10.3989/ic.14.116.
)
analysed the structural behaviour of the shell with a 3D laser scan,
comparing its present condition to the design specifications. Despite
the substantial 373 mm drop at the tip of the overhang, their analysis
concluded that the shell complied with existing Spanish legislation on
structural safety (6565.
Presidencia del Gobierno (2008) Real Decreto 1247/2008, de 18 de julio,
por el que se aprueba la instrucción de hormigón estructural
(EHE-08). Boletín Oficial del Estado, nº 203, 35176-35178 y Suplemento.
).
Although a cover of up to 40 mm was specified for the slab (Table 3), according to the GPR findings (Figure 13)
the concrete protecting the reinforcement from potential
environmentally-induced corrosion is <30 mm. In some sporadic
instances there is no cover whatsoever (Figure 10), due to the difficulties involved in laying the forms and positioning the reinforcement described by Cassinello et al. (3737. Cassinello, F.; Torroja, J.A.; Morán, F.; Fernández, F. (1969) Morfogénesis de una lámina, España. Infor. Constr. 22 [214], 3-28. https://doi.org/10.3989/ic.1969.v22.i214.3659.
).
Those problems were exacerbated by design specifications calling for a
cover of just 10 mm at the unrestrained edge of the structure (Table 3).
The electrical resistivity and corrosion potential findings revealed that the risk of active corrosion in the slab concrete is low at this time (Figure 14), for like in the pergola, the threshold value indicative of steel de-passivation has not been reached.
The dimensionless Schmidt hammer test measurements, at 56±4, denote concrete uniformity, whilst the sole differences in shell moisture content are orientation-dependent, with higher values in the north-facing (39 %) than in the west-facing (26 %) areas.
3.3. Window Frame
⌅3.3.1. Historic background and damage mapping
⌅The
building’s 400 low-strength, 1.60 m high window frames were cast at an
on-site workshop using mortar with a sand:(white) cement ratio of 1:2.
Bearing capacity is provided by the likewise 1.60 m long lintels and the
vertical supports (concrete columns). The reinforced concrete columns
were cast between the windows into forms comprising the vertical members
in the two adjacent window frames as the sides, the indoor building
façade at the rear and temporary corrugated sheet steel panel across the
front. The latter stripped served as ornamentation in this inter-window
space (3939. Eymar, J.M. (1999) Prefabricación. Infor. Constr. 51[462], 43-62. https://doi.org/10.3989/ic.1999.v51.i462.858.
) (Figure 15).
).
The frames have been repainted on a number of occasions predating this analysis.
The present damage map shows both corrosion issues and some cracking. The most prominent problem observed was clogged drainage and the resulting ponding of water in the top member. That in turn has often generated further damage in the form of mortar corrosion and crumbling due to cementitious matrix dissolution. Part of one of the corners on the lintel in poorest condition was observed to have detached completely in response to corrosion (Figure 16).
3.3.2. Mortar characterisation
⌅A 29 cm long, 0.87 kg sample was cored from an area in the lintel on one of the windows on the south side of the building where top reinforcement corrosion had induced severe spalling (Table 4).
Design characteristics (3939. Eymar, J.M. (1999) Prefabricación. Infor. Constr. 51[462], 43-62. https://doi.org/10.3989/ic.1999.v51.i462.858. , 5757. Centro Experimental de Arquitectura (1948) Pliego general de condiciones varias de la edificación. Título 1, Condiciones generales de índole técnica; aprobado por el Consejo Superior de los Colegios de Arquitectos; adoptado en las Obras de la Dirección General de Arquitectura. Madrid. ) |
Findings in this study | |
---|---|---|
Hg intrusion porosity (vol%) | 13.7 ± 0.6 | |
Density (g/cm3) | 2.3 ± 0.1 | |
Cement:sand ratio | 1:2 (cement:sand) | 1:1.7 |
Type of cement | white cement | white cement |
Sand aggregate | Siliceous sand | Siliceous sand (quartz, potassium feldspar and plagioclase) |
Moisture (%) | 31.7-39.7 | |
Ultrasound pulse velocity (m/s) | 4054 | |
Ultrasound-determined longitudinal MOE (MOEus) (GPa) | 41.1 | |
Carbonation depth (mm) | 1.7 ± 0.6 |
The petrographic and SEM/EDX (Figure 17)
analyses conducted on the sample to characterise the mortar showed that
the sand (d/D=0.1/4) comprised well-graded, sub-angular monocrystalline
(together with some polycrystalline) quartz grains ranging in size from
100 µm to 4 mm and smaller (250 µm to 3 mm) angular potassium feldspar
particles (Table 4).
A minor fraction (around 10 %) of 0.5 mm to 1.5 mm plagioclase was also
present. Briefly, the design specified the same mineralogy for the
mortar sand as for the concrete fines (5757.
Centro Experimental de Arquitectura (1948) Pliego general de
condiciones varias de la edificación. Título 1, Condiciones generales de
índole técnica; aprobado por el Consejo Superior de los Colegios de
Arquitectos; adoptado en las Obras de la Dirección General de
Arquitectura. Madrid.
).
In addition to the intense quartz and feldspar reflections, the XRD pattern (Figure 18) exhibited signals attributed to mica, hydrated cement phases ettringite and portlandite and cement paste carbonation-induced calcite, all confirmed by FT-IR analysis (Figure 18).
DTA/TG-quantified portlandite content came to 3.7 wt% and calcite content to 10 wt% to 12 wt%. The broad, asymmetrical DTA signal for CaCO3 decarbonation denoted the low crystallinity of that compound.
A comparison of HCl dissolution-based solubility to the TG findings for the sample (4646.
ASTM C1084-19 (2019) Standard Test Method for Portland-Cement Content
of Hardened Hydraulic-Cement Concrete. West Conshohocken: ASTM
International.
) yielded a cement:sand ratio of 1:1.7, only slightly lower than the design specification.
Despite the well-graded quality of the sand, the mortar is fairly porous, exhibiting mean porosity of 13.7 % (Figure 19),
with pores <1 µm accounting for 9 %. Those data, found with mercury
intrusion porosimetric techniques, are not comparable to the
water-accessible porosity findings described above, however, for the two
parameters measure different size pores, the former in the 3 nm to 350
µm range and the latter 50 nm pores only (6666.
Kéri, A.; Sápi, A.; Ungor, D.; Sebok, D.; Csapó, E.; Kónya, Z.;
Galbács, G. (2020) Porosity determination of nano- and sub-micron
particles by single particle inductively coupled plasma mass
spectrometry. J. Anal. Atomic Spectrom. 35 1139-1147. https://doi.org/10.1039/D0JA00020E.
).
Nonetheless, at 41.1 GPa the Young’s modulus value denotes high mortar quality, although compressive strength could not be determined due to the irregular shape of the sample.
The carbonation depth observed is shallow (mean=1.7 mm), with CO2 penetration reaching up to 16 mm in only one area, affected by cracking (Table 4).
3.3.3. In-situ testing
⌅The mean thickness of the concrete covering the reinforcement in the precast window frames was also determined. The minimum design thickness was 6 mm (Figure 15), whilst in situ GPR delivered a mean of 15 mm (in the south-facing window the readings were more scattered than in the north, with a maximum thickness of 40 mm and minimum of 0 mm).
Similar moisture content values (32 % to 40 %) were found for the north and south façade vertical framing, whereas content was greater in the south- than in the north-facing lintels. The explanation may lie in the larger size of the south frame lintels, splashed by the rainwater gushing out of the rooftop gargoyles (Figure 16).
The Schmidt hammer rebound values were essentially identical for the north and south frames, with means of 56 and 57, respectively.
4. CONCLUSIONS
⌅The growing awareness of the cultural significance of 20th century concrete construction works makes imperative an adequate strategy for their preservation for future. Therefore, a strategy based on the continuous monitoring, different from an isolated and purely technical approach, is necessary to first minimize the maintenance required and secondly to propose more respectful interventions. This investigation presents the results of this first characterization and diagnosis phase of three singular concrete or mortars elements at the headquarters of the Eduardo Torroja Institute for Construction in Madrid, Spain. In a following subsection (4.1. Strategy for maintenance) a preliminary protection and prevention proposal is presented for the future application and validation of a selection of novel products developed in the InnovaConcrete project.
The structures, representative of distinct stages in the building construction, were selected for their cultural, historical, aesthetic, social and technological significance in the modern architecture movement within the InnovaConcrete Project.
They were assessed on the grounds of a compilation of the information on building construction, structural analysis of the respective members and characterisation of the constituent materials.
The present condition of the structures, built with essentially no deviation from the initial design are listed below.
General: Judging from Schmidt hammer and ultrasonic velocity measurements, the key structures are all in good condition.
Car park pergola: Even though the core samples proved to be in good condition, the aesthetic value of this element is compromised by the presence of reinforcement-induced cracking around the tips and top surface microcracking attributable to the failure to vibrate the concrete during casting and subsequent biological colonisation. Although with rare presence of exposed reinforcement, in-situ corrosion analyses denoted low risk of corrosion.
Rib-like shell: The samples cored from the slab of the rib-like shell were likewise in good condition, better in fact than observed in the pergola. Although with presence of exposed reinforcement, no risk of active corrosion was identified in the slab whereas in the shell itself exposed reinforcement is observed. The porosity of the upper surface of the concrete, without any protection, is the cause of subsequent biological colonization.
Window frame: The window frame lintels are not in optimal condition, exhibiting spalling and detachment due to faulty drainage that favour water ponding. The scant coating of the reinforcement has made numerous corrosion points visible.
4.1. Strategy for maintenance
⌅The proposals for intervention to preserve their monumental, artistic and historic values are listed below:
General: Except for the presence of reinforcement-induced cracking around the tips of some pergola in the car park and the cogged drain holes in the window frames, conservation of the elements analysed only requires superficial protection and prevention interventions.
Car park pergola: Cleaning and protection with compatible products are now imperative. Whilst both laboratory and in-situ corrosion analyses denoted low risk of corrosion, application of inhibitors to the exposed steel bars is recommended to prevent surface corrosion. The conservation strategy might be supplemented with the use of micromortars to seal cracks and consolidants to deter material loss. After cleaning, the top of the horizontal elements should be coated with a water repellent to minimise biological colonisation and water access. Cracking around the tips will require the use of repair mortars also compatible with existing materials.
Rib-like shell: No risk of active corrosion was identified in the slab, whereas the presence of exposed reinforcement in some areas suggests that the shell would benefit from the application of corrosion inhibitors and repair mortars. These operations should be supplemented with shell cleaning at the top side, more exposed to rainwater, which should be coated with water repellents to minimise biological colonisation.
Window frame: One possible solution to the problem posed by the small and readily cogged drain holes might consist in enlarging the holes and monitoring the results for some time to determine whether that, in conjunction with periodic cleaning, suffices to ensure effective drainage. After surface cleaning and drainage retooling, material losses should be patch repaired with corrosion inhibitors and water-repellent micromortars. The upper side of the lintels should be treated with water-repellents products to enhance their impermeability.
Given the heritage value of these elements, the techniques and treatments prescribed for their conservation must be verified for chemical and aesthetic compatibility, as well as durability.