Acta Scientiarum Polonorum Architectura
Szkoła Główna Gospodarstwa Wiejskiego w Warszawie
1644-0633
Optimizing the spatial configurations of an urban open space: syntactic analysis of the restored Hatirjheel wetland, Dhaka
ORIGINAL_ARTICLE
3-16
2021
15
2
Md Arifur
Rahman
Ahmed, B., Hasan, R. & Maniruzzaman, K. M. (2014). Urban
morphological change analysis of Dhaka city, Bangladesh,
using space syntax. ISPRS International Journal
of Geo-Information, 3 (4), 1412–1444. https://doi.
org/10.3390/ijgi3041412
An, Z., Chen, Q. & Li, J. (2020). Ecological Strategies of
Urban Ecological Parks – A case of Bishan Ang Mo
Kio Park and Kallang River in Singapore. E3S Web of
Conferences, 194, 05060. https://doi.org/10.1051/e3sconf/
202019405060
Architecture Master Prize (2016). Urban Oasis: Integrated
Development of Hatirjheel Area Including Begunbari
Canal, Dhaka, Bangladesh. Retrieved from: https://architectureprize.
com/winners/winner.php?id=2765 [access
21.06.2020].
Bentley, I., McGlynn, S., Smith, G., Alcock, A. & Murrain,
P. (1985). Responsive Environments: A Manual for Designers.
Oxford, UK: Routledge.
Castillo, M. M. (2013). Urban patterns and disaster risk:
The informal city on the hills. In Y. O. Kim, H. T. Park,
& K. W. Seo (Eds.), Proceedings of the Ninth International
Space Syntax Symposium (pp. 1-13). Seoul:
Sejong University Press. Retrieved from: http://sss9sejong.
or.kr/paperpdf/ussecp/SSS9_2013_REF114_P.pdf
[access 10.12.2020].
Duan, Z. Y. & Wang, Q. (2009). Road network analysis and
evaluation of Huizhou city based on space syntax. In
Proceedings of the 2009 International Conference on
Measuring Technology and Mechatronics Automation,
Zhangjiajie, China. Vol. 3 (pp. 579–582). https://doi.
org/10.1109/ICMTMA.2009.505
Feng, S., Chen, L., Sun, R., Feng, Z., Li, J., Khan, M. S.
& Jing, Y. (2019). The distribution and accessibility of
urban parks in Beijing, China: Implications of social
equity. International Journal of Environmental Research
and Public Health, 16 (24), 4894. https://doi.
org/10.3390/ijerph16244894
Foltête, J. & Piombini, A. (2007). Urban layout, landscape
features and pedestrian usage. Landscape and Urban
Planning, 81 (3), 225–234. https://doi.org/10.1016/j.landurbplan.
2006.12.001
Froy, F. E. (2016). Understanding the spatial organisation
of economic activities in early 19th century Antwerp.
The Journal of Space Syntax, 6 (2), 225–246. Retrieved
from: http://joss.bartlett.ucl.ac.uk/journal/index.php/
joss/article/view/287/pdf [access 10.12.2020].
Gehl, J. (1987). Life between buildings: using public space
(transl. by J. Koch). New York: Van Nostrand Reinhold.
Giannopoulou, M., Roukounis, Y. & Stefanis, V. (2012).
Traffic network and the urban environment: an adapted
space syntax approach. Procedia – Social and Behavioral
Sciences, 48, 1887–1896. https://doi.org/10.1016/
j.sbspro.2012.06.1163
Government of Bangladesh & Rajdhani Unnayan Kartripakkha
[GoB & RAJUK] (1995). Dhaka Metropolitan
Development Plan (1995–2015): Structure Plan, Master
Plan and Detailed Area Plan for Dhaka City. Urban
area plan (1995–2005). Vol. 2. Dhaka: Author.
Griffiths, S. (2011). Temporality in Hillier and Hanson’s
theory of spatial description: Some implications
of historical research for space syntax. The Journal
of Space Syntax, 2 (1), 73–96. Retrieved from:
http://128.40.150.106/joss/index.php/joss/article/
view/58/pdf_38 [access 10.12.2020].
Griffiths, S. (2012). The use of space syntax in historical
research: current practice and future possibilities. In
M. Greene, J. Reyes & A. Castro (Eds.), Proceedings of
the Eighth International Space Syntax Symposium (pp.
1–26). Santiago de Chile: PUC. Retrieved from: http://
sss8.cl/8193.pdf [access 10.12.2020].
Haaland, C. & Bosch, C.K. (2015). Challenges and strategies
for urban green-space planning in cities undergoing
densification: a review. Urban Forestry and Urban
Greening, 14 (4), 760–771. https://doi.org/10.1016/
j.ufug.2015.07.009
Hillier, B. (1996). Space is the machine: A configurational
theory of architecture. Cambridge, UK: Cambridge University
Press.
Hillier, B. & Hanson, J. (1984). The social logic of space.
Cambridge, UK: Cambridge University Press. https://
doi.org/10.1017/CBO9780511597237
Hillier, B., Hanson, J. & Graham, H. (1987). Ideas are in
things: an application of the space syntax method to discovering
house genotypes. Environment and Planning
B: Planning and Design, 14 (4), 363–385. https://doi.
org/10.1068/b140363
Hillier, W. R. G., Hanson, J. & Peponis, J. (1987). Syntactic
analysis of settlements. Architecture et comportement
– Architecture and Behaviour, 3 (3), 217–231. Retrieved
from: http://discovery.ucl.ac.uk/86/1/hillier-etal-1987-
synactic-analysis-settlements.pdf [access 10.12.2020].
Hillier, B., Penn, A., Hanson, J., Grajewski, T. & Xu, J.
(1993). Natural movement: or, configuration and attraction
in urban pedestrian movement. Environment and
Planning B: Planning and Design, 20 (1), 29-66. https://
doi.org/10.1068/b200029
Islam, M., Mahmud, A. & Islam, S. M. D. (2015). Open
Space Management of Dhaka City, Bangladesh:
A Case Study on Parks and Playgrounds, International
Research Journal of Environment Sciences, 4 (12),
118–126. Retrieved from: http://www.isca.in/IJENS/
Archive/v4/i12/15.ISCA-IRJEVS-2015-238.pdf [access
12.12.2020].
Jacobs, J. (1961). The death and life of great American cities.
New York: Random House.
Karimi, K. & Vaughan, L. (2014). An evidence-based approach
to designing new cities: The English new towns
revisited. In M. Carmona (Ed.), Explorations in Urban
Design: An Urban Design Research Primer (pp. 261–
–276). Surrey, UK: Ashgate Publishing.
Khan, M. (2014). Study of open spaces in the context of
Dhaka city for sustainable use: A syntactic approach.
International Journal of Engineering and Technology,
6 (3), 118–126. https://doi.org/10.7763/IJET.2014.
V6.704
Kim, H. K. & Sohn, D. W. (2002). An analysis of the relationship
between land use density of office buildings and
urban street configuration: Case studies of two areas in
Seoul by space syntax analysis. Cities, 19 (6), 409–418.
https://doi.org/10.1016/S0264-2751(02)00071-9
Klarqvist, B. (1993). A Space Syntax Glossary. Nordic
Journal of Architectural Research, 2, 11–12. Retrieved
from: http://arkitekturforskning.net/na/article/view/778
[access 06.01.2021].
Koohsari, M. J., Kaczynski, A. T., Mcormack, G. R. &
Sugiyama, T. (2014). Using Space Syntax to Assess the
Built Environment for Physical Activity: Applications
to Research on Parks and Public Open Spaces. Leisure
Sciences, 36 (2), 206–216. https://doi.org/10.1080/0149
0400.2013.856722
Law, S., Karimi, K., Penn, A. & Chiaradia, A. (2013). Measuring
the influence of spatial configuration on the housing
market in metropolitan London. In Y. O. Kim, H. T.
Park & K. W. Seo (Eds.), Proceedings of the 2013 International
Space Syntax Symposium (pp. 1–20). Seul:
Sejong University Press. Retrieved from: http://sss9sejong.
or.kr/paperpdf/ussecp/SSS9_2013_REF121_P.pdf
[access 10.12.2020].
Lv, Y. & Guan, S. P. (2019). Exploration to the construction
pattern of Wetland Park – Taking Haizhu Wetland Park
as an example. MATEC Web of Conferences, 277, 03016.
https://doi.org/10.1051/matecconf/201927703016
Mohamed, A. A., Nes, A. van, Salheen, M. A., Kohlert, C. &
Schwander, C. (2013). The socio-economic implications
of the spatial configuration in greater Cairo metropolitan
area. In Y. O. Kim, H. T. Park & K. W. Seo (Eds.),
Proceedings of the Ninth international Space Syntax
Symposium (pp. 1–18). Seoul: Sejong University Press.
Retrieved from: http://resolver.tudelft.nl/uuid:68f2716cbdcf-
447e-8a80-d3b025b062a3 [access 10.12.2020].
Mowla, Q. A. (2013). Water Urbanism: A Prospective Study
on Dhaka. Turkish Online Journal of Science & Technology,
3 (3), 205–218. Retrieved from: https://www.
tojsat.net/journals/tojsat/volumes/tojsat-volume03-i03.
pdf [access 10.08.2020].
Nilufar, F. (1999). Urban life and public open space in
Dhaka. Report submitted to Asiatic Society of Bangladesh,
Dhaka. Retrieved from: https://www.academia.
edu/245120/Urban_life_and_use_of_Public_Space_in_
Dhaka [access 10.08.2020].
Nilufar, F. (2015). Preserving open space for livability
of Dhaka. Paper presented at the World Habitat Day
2015 Seminar, Housing and Public Works Ministry,
GoB, Dhaka. Retrieved from: https://www.academia.
edu/19511365/PRESERVING_OPEN_SPACE_FOR_
LIVABILITY_OF_DHAKA [access 12.08.2020].
Omer, I. & Zafrir-Reuven, O. (2010). Street patterns and spatial
integration of Israeli cities. The Journal of Space Syntax,
1 (2), 295. Retrieved from: http://128.40.150.106/joss/index.
php/joss/article/view/280/pdf_24 [access 10.12.2020].
Pedersen, E., Weisner, S. E. B. & Johansson, M. (2019).
Wetland areas’ direct contributions to residents’ well-being
entitle them to high cultural ecosystem values. Science
of the Total Environment, 646, 1315–1326. https://
doi.org/10.1016/j.scitotenv.2018.07.236
Ratti, C. (2004). Space Syntax: Some Inconsistencies. Environment
and Planning B: Planning and Design, 31 (4),
487–499. https://doi.org/10.1068/b3019
Schipperijn, J., Stigsdotter, U. K., Randrup, T. B. & Troelsen,
J. (2010). Influences on the Use of Urban Green
Space- A Case Study in Odense, Denmark. Urban
Forestry & Urban Greening, 9 (1), 25–32. https://doi.
org/10.1016/j.ufug.2009.09.002
Song, S., Albert, C. & Prominski, M. (2020). Exploring integrated
design guidelines for urban wetland parks in China.
Urban Forestry and Urban Greening, 53, 126712.
https://doi.org/10.1016/j.ufug.2020.126712
Srinurak, N. & Mishima, N. (2017). Urban Axis and City
shape evaluation through spatial configuration in
‘Lan Na’ Northern Thailand Historic city. City, Territory
and Architecture, 4 (1), 10. https://doi.org/10.1186/
s40410-017-0067-z
Tabassum, S. & Sharmin, F. (2013). Accessibility analysis
of parks at urban neighbourhood: The case of Dhaka.
Asian Journal of Applied Science and Engineering, 2 (2),
48–61. Retrieved from: http://publicationslist.org/data/
ajase/ref-46/51_4_Template.pdf [access 10.08.2020].
Tariq, T. & Nilufar, F. (2013). Integrating the Recreational
spaces of Rangpur City Corporation, Bangladesh: A perspective
from space syntax. In Y. O. Kim, H. T. Park &
K. W. Seo (Eds.), Proceedings of the 2013 International
Space Syntax Symposium (pp. 1–15). Seoul: Sejong
University Press. Retrieved from: http://sss9sejong.
or.kr/paperpdf/ussecp/SSS9_2013_REF119_P.pdf [access
10.08.2020].
Thompson, C. W. (2002). Urban open space in the 21st century.
Landscape and Urban Planning, 60 (2), 59–72.
https://doi.org/10.1016/S0169-2046(02)00059-2
Vitti Sthapati Brindo Limited (2015). Integrated Development
of Hatirjheel Area Including Begunbari Canal.
Dhaka, Bangladesh. Retrieved from: http://vitti.com.
bd/project/integrated-development-of-hatirjheel-area/
#ad-image-852 [access 21.06.2020].
Wei, F. (2017). Greener urbanization? Changing accessibility
to parks in China. Landscape and Urban Planning,
157, 542–552. https://doi.org/10.1016/j.landurbplan.20
16.09.004
Wu, L., Liu, X., Ye, X., Leipnik, M., Lee, J. & Zhu, X. (2015).
Permeability, space syntax, and the patterning of residential
burglaries in urban China. Applied Geography, 60,
261–265. https://doi.org/10.1016/j.apgeog.2014.12.001
10.22630/ASPA/2021.2.
On the method of calculation of buckling and post-buckling behavior of laminated shells with small arbitrary imperfections
ORIGINAL_ARTICLE
17-25
2021
15
2
Mykola
Semenyuk
Volodymyr
Trach
Natalia
Zhukova
Amazigo, J. C. & Fraser, W. B. (1971). Buckling under external
pressure of cylindrical shells with dimple shaped
initial imperfections. International Journal of Solids
and Structures, 7 (8), 883–900.
Bazhenov, V. A., Semenyuk, N. P. & Trach, V. M. (2010).
Neliniyne deformuvannya, stiykist i zakrytychna povedinka
anizotropnykh obolonok [Nonlinear deformation,
stability and postbuckling behavior of anisotropic
shells]. Kyiv: Caravela.
Byskov, E. (2004). Mode Interaction in Structures – An
Overview. In Proceedings of the Sixth World Congress
on Computational Mechanics in conjunction with the
Second Asian-Pacific Congress on Computational Mechanics:
Sept. 5-10, 2004, Beijing, China. Beijing: Tsinghua
University [CD-ROM].
Byskov, E. & Hutchinson, J. W. (1977). Mode interaction
in axially stiffened cylindrical shells. AIAA Journal,
15 (7), 941–948.
Koiter, W. T. (1963). Elastic Stability and Post Buckling Behaviour
in Nonlinear Problems. In Nonlinear Problems.
Proceedings of a Symposium (pp. 257–275). Madison,
WI: University of Wisconsin Press.
Koiter, W. T. (1976). General theory of mode interaction in
stiffened plate and shell structures (Report WTHD 91).
Delft: Delft University of Technology.
Vanin, G. A. & Semenyuk, N. P. (1987). Ustoychivost obolochek
iz kompozitsionnykh materialov s nesovershenstvami
[Stability of composite shells with imperfections].
Kyiv: Naukova Dumka.
10.22630/ASPA/2021.2.
Static analysis of a variable cross-section element under load
ORIGINAL_ARTICLE
27-40
2021
15
2
Jan
Zamorowski
Barszcz, A. & Giżejowski, M. (2006). Analiza zaawansowana
w projektowaniu konstrukcji stalowych wg Eurokodu
3. Inżynieria i Budownictwo, 9, 501–506.
Belyayev, H. M. (1956). Soprotivleniye materialov. Moskva:
GIT-TL.
Czepiżak, D. (2006). Nośność graniczna lokalnie wzmocnionych
wieloprzęsłowych blach fałdowych (PhD dissertation).
Instytut Budownictwa Politechnika Wrocławska,
Wrocław.
Dassault Systèmes (2013). Abaqus 6.13 Online Documentation.
Providence, RI: Dassault Systèmes Simulia Corporation.
Retrieved from: http://130.149.89.49:2080/
v6.13/index.html [access 02.04.2013].
ERGOCAD (2020). ConSteel 14 User Manual. Retrieved
from: https://www.consteelsoftware.eu/uploads/
9/9/7/7/99772912/consteel_14_user_manual [access
20.05.2020].
European Committee for Standardization [CEN] (2006).
Eurocode 3. Design of steel structures. Part 1–3: General
rules. Supplementary rules for cold-formed members
and sheeting (EN 1993-1-3:2006). Brussels: European
Committee for Standardization.
Girkmann, K. (1956). Flächentragwerke. Wien: Springer-
-Verlag.
Giżejowski, M., Szczerba, R., Gajewski, M. & Stachura,
Z. (2015). Analiza nośności stalowej ramy płaskiej
o blachownicowych elementach smukłościennych [Resistance
assessment of steelplanarframefabricated from
slender web plategirders]. Czasopismo Inżynierii Lądowej,
Środowiska i Architektury – Journal of Civil
Engineering, Environment and Architecture, 62 (4/15),
73–92.
Juraszek, J. (2019). Residual magnetic field for identification
of damage in steel wire rope [Identyfikacja uszkodzeń
lin stalowych za pomocą rezydualnego pola magnetycznego].
Archives of Mining Sciences, 64 (1), 79–92.
https://doi.org/10.24425/ams.2019.126273
Juraszek, J. (2020). Fiber Bragg sensors on strain analysis
of power transmission lines. Materials, 13 (7), 1559.
https://doi.org/10.3390/ma13071559
Polski Komitet Normalizacyjny [PKN] (2008). Eurokod 3.
Projektowanie konstrukcji stalowych. Część 1–3: Reguły
ogólne. Reguły uzupełniające dla konstrukcji z kształtowników
i blach profilowanych na zimno (PN-EN 1993-
-1-3:2008). Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2010). Eurokod 1.
Oddziaływania na konstrukcje. Część 1–4: Oddziaływania
ogólne. Oddziaływania wiatru (PN-EN 1991-1-7:2008/
/NA:2010). Warszawa: Polski Komitet Normalizacyjny.
Zamorowski, J. (2013). Przestrzenne konstrukcje prętowe
z geometrycznymi imperfekcjami i podatnymi węzłami
[Spatial bar structures with geometrics imperfections
and flexible nodes]. Gliwice: Wydawnictwo Politechniki
Śląskiej.
10.22630/ASPA/2021.2.
Digital survey of damages on the façade of a historical building
ORIGINAL_ARTICLE
41-50
2021
15
2
Joanna A.
Pawłowicz
Bernat, M., Byzdra, A., Chmielecki, M., Laskowski, P.,
Orzechowski, J., Rzepa, S., Szulwic, J. & Ziółkowski P.
(2016). Zastosowanie naziemnego skaningu laserowego
i przetwarzanie danych: inwentaryzacja i inspekcja
obiektów budowlanych. Przegląd technologii i przykłady
zastosowań. Gdańsk: Wydawnictwo Polskiego Internetowego
Informatora Geodezyjnego.
Ćmielewski, B. (2011). Identification deformation areas
of slops using terrestrial laser scanner-preliminary research.
In Proceedings of the 13th Professional Conference
of Postgraduate Students (Juniorstav 2011). Brno:
Akademické nakladatelství CERM.
Franceschi, M., Teza, G., Preto, N., Pesci, A., Galgaro, A.
& Girardi, S. (2009). Discrimination between marls
and limestone using intensity data from terrestrial laser
scanner. ISPRS Journal of Photogrammetry and Remote
Sensing, 64 (6), 522–528. https://doi.org/10.1016/
j.isprsjprs.2009.03.003
Janowski, A., Nagrodzka-Godycka, K., Szulwic, J. & Ziolkowski,
P. (2016). Remote sensing and photogrammetry
techniques in diagnostics of concrete structures.
Computers and Concrete, 18 (3), 405–420. https://doi.
org/10.12989/cac.2016.18.3.405
Kaspar, M., Pospisil, J., Stroner, M., Kremen, T. & Tejkal,
M. (2004). Laser Scanning in civil engineering and land
surveying. Hradec Králové: Vega.
Pawłowicz, J. A. (2017). Importance of Laser Scanning
Resolution in the Process of Recreating the Architectural
Details of Historical Buildings. IOP Conference Series:
Materials Science and Engineering, 245 (5), 052038.
https://doi.org/10.1088/1757-899X/245/5/052038
Pawłowicz, J. A., Bilko, P., Sawczyński, S. & Szafranko, E.
(2017). Diagnostic of Geometry Distortion of a Wooden
Structure Based on a Point Cloud. In 2017 Baltic Geodetic
Congress (BGC Geomatics) (pp. 163–168). IEEE.
https://doi.org/10.1109/BGC.Geomatics.2017.55
Szafranko, E. (2014). Ways to determine criteria in multicriteria
methods applied to assessment of variants of
a planned building investment. Czasopismo Techniczne.
Budownictwo, 2-B (6), 41–48. https://doi.org/10.4467/
2353737XCT.14.110.2560
Van Genechten, B. & Schueremans, L. (2009) Laserscanning
for heritage documentation. Wiadomości Konserwatorskie,
26, 727–737.
Wehr, A. & Lohr, U. (1999). Airborne laser scanning – an introduction
and overview. ISPRS Journal of Photogrammetry and Remote Sensing, 54 (2–3), 68–82. https://doi.
org/10.1016/S0924-2716(99)00011-8
Wujanz, D., Burger, M., Tschirschwitz, F., Nietzschmann,
T., Neitzel, F. & Kersten, T. (2018). Determination of
Intensity-Based Stochastic Models for Terrestrial Laser
Scanners Utilising 3D-Point Clouds. Sensors, 18 (7),
2187. https://doi.org/10.3390/s18072187
Zaczek-Peplinska, J., Góra, A. & Grzyb, M. (2015). Analiza
statystyczna wartości Intensity (TLS) zarejestrowanych
na powierzchni konstrukcji betonowej. In M. Kwaśniak
(Ed.), Techniki inwentaryzacji i monitoringu obiektów
inżynierskich (pp. 90–105). Warszawa, Wydział Geodezji
i Kartografii Politechniki Warszawskiej.
10.22630/ASPA/2021.2.
Renovation of buildings having damp and salted walls – case analyses
ORIGINAL_ARTICLE
51-64
2021
15
2
Wacław
Brachaczek
Bajno, D. & Budnik, N. (2019). Wybrane problemy oceny
stanu technicznego budynków i budowli w aspekcie
późniejszej naprawy i wzmocnienia [Selected problems
of assessment of the technical condition of buildings and
construction in the aspect of later repairs and reinforcements].
Materiały Budowlane, 3, 18–19. https://doi.
org/10.15199/33.2019.03.05
Brachaczek, W. (2018a). Kształtowanie właściwości
współczesnych tynków renowacyjnych [Shaping the
properties of modern renovation plasters]. Kraków:
Polska Akademia Nauk. Oddział w Krakowie, Polskie
Towarzystwo Ceramiczne.
Brachaczek, W. (2018b). Study of the Impact of Microstructure
and Sorption Properties of the Renovation Plasters
on the Wall Drying Rate. Periodica Polytechnica Civil
Engineering, 62 (3), 792–799. https://doi.org/10.3311/
PPci.11822
Charola, A. E. (2000). Salts in the deterioration of porous
materials: an overview. Journal of the American Institute
for Conservation, 39 (3), 327–343. https://doi.org/1
0.1179/019713600806113176
Dudás, A. & Terjék, A. (2015). Efficiency assessment of
posterior waterproofing systems of renovated porous
limestone masonry work. Tehnički vjesnik – Technical
gazette, 22 (5), 1225–1236. https://doi.org/10.17559/
TV-20140715083036
Gorecki, P. & Wyrwał, J. (2010). Proces niszczenia murów
ceglanych w zabytkowych budynkach i obiektach przemysłowych
[Degradation process of old brick walls in
monumental and industrial building]. Roczniki Inżynierii
Budowlanej, 10, 25–30.
Gosztyła, M., Leś, S. & Sikorski, K. (2017). Stary rynek
w Rzeszowie – tynki stosowane w procesie renowacji
obiektów zabytkowych. Aspekty technologiczne [Old
Market in Rzeszow – plasters used during restoration
works of historical buildings. Technological aspects].
Czasopismo Inżynierii Lądowej, Środowiska i Architektury
– Journal of Civil Engineering, Environment and
Architecture, 64 (4/I), 89–103. https://doi.org/10.7862/
rb.2017.195
Hall, C. & Hoff, W. D. (2007). Rising damp: capillary
rise dynamics in walls. Proceedings of the Royal Society
A: Mathematical, Physical and Engineering Sciences,
463 (2084), 1871–1884. https://doi.org/10.1098/
rspa.2007.1855
Hughes, J. J., Groot, C., Van Balen, K., Bicer-Simsir, B.,
Binda, L., Elsen, J., Hees, R. P. J. van, Konow, T. von,
Lindqvist, J. E., Maurenbrecher, P., Papayianni, I.,
Subercaseaux, M., Tedeschi, C., Toumbakari, E-E.,
Thompson, M., Valek, J. & Do Rosário Veiga, M.
(2012). RILEM TC 203-RHM Repair mortars for historic
masonry: The role of mortar in masonry: an introduction
to requirements for the design of repair mortars.
Materials and Structures, 45 (9), 1287–1294. https://doi.
org/10.1617/s11527-012-9916-0
Lubelli, B., Hees, R. P. J. van & Groot, C. J. W. P. (2006).
Sodium chloride crystallization in a “salt transporting”
restoration plaster. Cement and Concrete Research,
36 (8), 1467–1474. https://doi.org/10.1016/
j.cemconres.2006.03.027
Misiewicz, J. (2016). Adaptacja zabytkowej kamienicy Naujacka
na Centrum Kultury w Olsztynie [Adaptation of
a historical Naujack tenement house – transformation
into the Olsztyn Cultural Centre]. Przegląd Budowlany,
87 (6), 19–28.
Pavlíková, M., Pavlík, Z., Keppert, M. & Černý, R. (2011).
Salt transport and storage parameters of renovation
plasters and their possible effects on restored buildings’
walls. Construction and Building Materials, 25 (3),
1205–1212. https://doi.org/10.1016/j.conbuildmat.2010.
09.034
Petković, J., Huinink, H. P., Pel, L., Kopinga, K. & Hees,
R. P. J. van (2010). Moisture and salt transport in three-
-layer plaster/substrate systems. Construction and Building
Materials, 24 (1), 118–127. https://doi.org/10.1016/
j.conbuildmat.2009.08.014
Polski Komitet Normalizacyjny [PKN] (2002). Cieplno-
-wilgotnościowe właściwości materiałów i wyrobów budowlanych.
Określanie wilgotności przez suszenie w podwyższonej
temperaturze (PN-EN ISO 12570:2002).
Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2003). Metody badań
zapraw do murów. Część 18: Określenie współczynnika
absorpcji wody spowodowanej podciąganiem kapilarnym
stwardniałej zaprawy (PN-EN 1015-18:2003).
Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2016). Wymagania
dotyczące zaprawy do murów. Część 1: Zaprawa
do tynkowania zewnętrznego i wewnętrznego (PN-EN
998-1:2016-12). Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2019a). Badania
betonu. Część 3: Wytrzymałość na ściskanie próbek do
badań (PN-EN 12390-3:2019-07). Warszawa: Polski
Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2019b). Badania
betonu. Część 5: Wytrzymałość na zginanie próbek do
badań (PN-EN 12390-5:2019-08). Warszawa: Polski
Komitet Normalizacyjny.
Wissenschaftlich-Technische Arbeitsgemeinschaft für Bauwerkserhaltung
und Denkmalpflege e.V. [WTA] (1999).
Beurteilung von Mauerwerk – Mauerwerksdiagnostik
(WTA 4-5-99/D). München: Fraunhofer IRB Verlag.
Wissenschaftlich-Technische Arbeitsgemeinschaft für Bauwerkserhaltung
und Denkmalpflege e.V. [WTA] (2005).
Sanierputzsysteme (WTA 2-9-04/D). München: Fraunhofer
IRB Verlag.
10.22630/ASPA/2021.2.
Circular economy in housing architecture: methods of implementation
ORIGINAL_ARTICLE
65-74
2021
15
2
Łukasz Kamil
Mazur
Budds, D. (2016-10-26). This Dutch Company Turns
Demolished Buildings into Beautiful Materials.
Fast Company. Retrieved from: https://www.fastcompany.
com/3064915/this-dutch-company-turnsdemolished-
buildings-into-beautiful-materials [access
15.03.2021].
Bukowski, H. & Fabrycka, W. (2019). Budownictwo
w obiegu zamkniętym w praktyce. Warszawa: INNOWO.
Retrieved from: https://innowo.org/userfiles/
publikacje/Budownictwo%20w%20obiegu%20zamk
ni%C4%99tym%20w%20praktyce_raport.pdf [access
15.03.2021].
Bulei, C., Kiss, I. & Alexa, V. (2021). Development of
metal matrix composites using recycled secondary raw
materials from aluminium wastes. Materials Today:
Proceedings, 45, 4143–4149. https://doi.org/10.1016/
j.matpr.2020.11.926
Communication from the Commission to the European Parliament
and the Council. Strategy for the sustainable
competitiveness of the construction sector and its enterprises.
COM(2012) 433 final.
Communication from the Commission to the European Parliament,
the Council, the European Economic and Social
Committee, the Committee of the Regions, and the
European Investment Bank. Accelerating Clean Energy
Innovation. COM(2016) 763 final.
Directorate-General for Climate Action [DG CLIMA]
(2019). Going climate-neutral by 2050. Luxembourg:
Publications Office of the European Union.
Delta Institute (2018). Deconstruction & building material
reuse: a tool for local governments & economic
development practitioner. Chicago: Delta Institute. Retrieved
from: www.delta-institute.org/wp-content/uploads/
2018/05/Deconstruction-Go-Guide-6-13-18-.pdf
[access 24.01.2021].
Eberhardt, L. C. M., Birgisdottir, H. & Birkved, M. (2019).
Potential of Circular Economy in Sustainable Buildings.
IOP Conference Series: Materials Science and Engineering,
471 (9), 1–10. https://doi.org/10.1088/1757-
899X/471/9/092051
Eberhardt, L. C. M., Birgisdottir, H. & Birkved, M. (2020-
-06-23). Building design and construction strategies for
a circular economy. Architectural Engineering and Design
Management. https://doi.org/10.1080/17452007.20
20.1781588
Ellen MacArthur Foundation & ARUP (2019). Circular
economy in cities. Ellen MacArthur Foundation.
Retrieved from: www.ellenmacarthurfoundation.org
/assets/downloads/Buildings_All_Mar19.pdf [access
29.03.2021].
Eurostat (2020a). Housing statistics. Housing quality. Retrieved
from: www.ec.europa.eu/eurostat/statistics-explained/
index.php/Housing_statistics#Housing_quality
[access 24.03.2021].
Eurostat (2020b). Waste statistics. Total waste generation
[env_wasgen]. Retrieved from: www.ec.europa.
eu/eurostat/statistics-explained/index.php/Waste_
statistics#Total_waste_generation [access 15.08.2020].
Firląg, S. (2019). Kompleksowa termomodernizacja budynków
jednorodzinnych. Warszawa: Fundacja Ziemia
i Ludzie.
Fritz Benachio, G. L., Carmo Duarte Freitas, M. & Tavares,
S. F. (2020). Circular economy in the construction industry:
A systematic literature review. Journal of Cleaner
Production, 260, 121046. https://doi.org/10.1016/
j.jclepro.2020.121046
Gadgil, A. J. & Cherukumilli, K. (2019). Advances in Water
Purification Techniques. Meeting the Needs of Developed
and Developing Countries. In S. Ahuja (Ed.),
Addressing Groundwater Fluoride Contamination Using
Inexpensively Processed Bauxite (pp. 291–325).
Calabash: Elsevier. https://doi.org/10.1016/B978-0-12-
814790-0.00012-0
Ginga, C. P., Ongpengand, J. M. C. & Daly, M. K. M.
(2020). Circular Economy on Construction and Demolition
Waste: A Literature Review on Material Recovery
and Production. Materials, 13, 2970. https://doi.
org/10.3390/ma13132970
Global Aluminium Recycling Committee [GARC] (2009).
Global Aluminium Recycling: A Cornerstone of Sustainable
Development. Haymarket–London: International
Aluminium Institute. Retrieved from: www.world-aluminium.
org/media/filer_public/2013/01/15/fl0000181.
pdf [access 15.03.2021].
Kellner, J. (2011). Housing Reclaimed: Sustainable Homes
for Next to Nothing. Canada: New Society Publishers.
Kleis, B. (2013). Upcycle house – Genbrug fra inderst til
yderst. Odense: Realdania Byg. Retrieved from: www.
realdaniabyogbygklubben.dk/media/1803/minico2-
husene-upcycle-house.pdf [access 29.03.2021].
Leube, M. & Walcher, D. (2017). Designing for the next
(Circular) Economy. An appeal to renew the Curricula
of Design Schools. The Design Journal, 20, 492–501.
https://doi.org/10.1080/14606925.2017.1352999
Lundell, C. & Thomas, J. (2020). PET: Polyethylene
Terephthalate – The Ubiquitous 500 ml Water Bottle. InG. Di Bucchianico et al. (Eds.), Advances in Industrial
Design. AHFE 2020. Advances in Intelligent Systems
and Computing. Vol. 1202. Cham: Springer. https://doi.
org/10.1007/978-3-030-51194-4_33
Mahpour, A. (2018). Prioritizing barriers to adopt circular
economy in construction and demolition waste management.
Resources, Conservation & Recycling, 134, 216–
–227. https://doi.org/10.1016/j.resconrec.2018.01.026
Marinova, S., Deetman, S., Voeta, E. & Daioglou, V. (2020).
Global construction materials database and stock analysis
of residential buildings between 1970-2050. Journal
of Cleaner Production, 247, 119146. https://doi.
org/10.1016/j.jclepro.2019.119146
Mestre, A. & Cooper, T. (2017). Circular Product Design.
A Multiple Loops Life Cycle Design Approach for the
Circular Economy. The Design Journal, 20, 1620–1635.
https://doi.org/10.1080/14606925.2017.1352686
Morgan, J. (2014). The Great Resource Price Shock. London:
Green Alliance.
Nerini, F. F., Slob, A., Engström, E. R. & Trutnevyte, E.
(2019). A Research and Innovation Agenda for Zero-
-Emission European Cities. Sustainability, 11, 1692. https://
doi.org/10.3390/su11061692
Núñez-Cacho, P., Górecki, J., Molina, V. & Corpas-Iglesias,
A. F. (2018). New Measures of Circular Economy
Thinking in Construction Companies. Journal of
EU Research in Business, 2018, 909360. https://doi.
org/10.5171/2018.909360
Organisation for Economic Co-operation and Development
[OECD] (2015). Material Resources, Productivity and
the Environment, OECD Green Growth Studies. Paris:
OECD Publishing. https://doi.org/10.1787/9789264190
504-en
Organisation for Economic Co-operation and Development
[OECD] (2017). Green Growth Indicators 2017, OECD
Green Growth Studies. Paris: OECD Publishing. https://
doi.org/10.1787/9789264268586-en
Russon, M-A. (2014-04-24). China: Recycled Concrete
Houses 3D-Printed in 24 Hours. International Business
Times. Retrieved from: www.ibtimes.co.uk/china-recycled-
concrete-houses-3d-printed-24-hours-1445981
[access 15.08.2020].
Scamans, G. M., Birbilis, N. & Buchheit, R. G. (2010).
Corrosion of Aluminum and its Alloys. Shreir’s Corrosion,
3, 1974–2010. https://doi.org/10.1016/B978-
044452787-5.00095-0
Smol, M., Kulczycka, J., Henclik, A., Gorazda, K. &
Wzorek, Z. (2015). The possible use of sewage sludge
ash (SSA) in the construction industry as a way towards
a circular economy. Journal of Cleaner Production, 95,
45–54. https://doi.org/10.1016/j.jclepro.2015.02.051
Tebbatt, A. K., Osmani, M., Thorpe, T. & Thornback, J.
(2017). Circular economy in construction: current awareness,
challenges, and enablers. Waste and Resource
Management, 170, 15–24. https://doi.org/10.1680/
jwarm.16.00011
Thelen, D., Acoleyen, V. M., Huurman, W., Thomaes, T.,
Brunschot, V. C., Edgerton, B. & Kubbinga B. (2018).
Scaling the circular built environment pathways for
business and government. World Business Council for
Sustainable Development & Circle Economy. Retrieved
from: https://docs.wbcsd.org/2018/12/Scaling_the_Circular_
Built_Environment-pathways_for_business_and_
government.pdf [access 15.03.2021].
United Nations Environment Programme [UNEP] (200).
Building and climate change. Summary for Decision
Makers. Nairobi: United Nations Environment
Programme. Retrieved from: https://www.uncclearn.
org/wp-content/uploads/library/unep207.pdf [access
15.03.2021].
Vilches, A., Garcia-Martinez, A. & Sanchez-Montanes, B.
(2017). Life cycle assessment (LCA) of building refurbishment:
a literature review. Energy and Buildings, 135,
1–61. https://doi.org/10.1016/j.enbuild.2016.11.042
Walther, J. V. (2014). Earth’s natural resources. Burlington:
Jones & Bartlett Learning.
Williams, J. (2019). Circular cities. Urban Studies, 56 (13),
2746–2762. https://doi.org/10.1177/0042098018806133
Winkless, L. (2016). These Houses Are Built With Blocks
Made From Waste Plastic. Retrieved from: www.
forbes.com/sites/lauriewinkless/2016/07/21/thesehouses-
are-built-with-blocks-made-from-waste-plastic/
#36632d7d7894 [access 15.08.2020].
Xu, K., Shen, G. Q., Liu, G. & Martek, I. (2019). Demolition
of Existing Buildings in Urban Renewal Projects: A
Decision Support System in the China Context. Sustainability,
11 (2), 491. https://doi.org/10.3390/su11020491
Yihe, M. (2019). WINSUN 3DPrinting. New
Era of Green Building [presentation]. Retrieved
from: www.3dprintetbyggeri.dk/pdf/
IDA%20konferencen%20PP/6.%20Winsun.pdf [access
15.08.2019].
Zaheer, A. & David, S. J. (2018). Towards a Circular Economy:
A Case Study of Waste Conversion into Housing
Units in Cotonou, Benin. Urban Science, 2 (4), 118.
https://doi.org/10.3390/urbansci2040118
10.22630/ASPA/2021.2.
Influence of solar radiation to the temperature inside a three-layer partition in winter season
ORIGINAL_ARTICLE
75-82
2021
15
2
Patrycja
Antonik-Popiołek
Ahola, S. & Lahdensivu, J. (2017). Long term monitoring of
repaired external wall assembly. Energy Procedia, 132,
375–380.
Cui, Y., Xie, J., Liu, J., & Xue, P. (2019). Experimental and
Theoretical Study on the Heat Transfer Coefficients of
Building External Surfaces in the Tropical Island Region.
Applied Sciences, 9, 1063. https://doi.org/10.3390/
app9061063
Gayo, E., Frutos, J. De, Palomo, A. & Massa, S. (1996).
A mathematical model simulating the evaporation processes
in building materials: Experimental checking
through infrared thermography. Building and Environment,
31 (5), 469–475.
Juraszek, J. (2019a). The influence of the spatial structure
of carbon fibers on the strength properties of a carbon
composite. Fibres & Textiles in Eastern Europe, 27 (3),
111–117.
Juraszek, J. (2019b). Residual Magnetic Field for Identification
of Damage in Steel Wire Rope. Archives of Mining
Science, 64 (1), 79–92.
Juraszek, J. (2019c). Residual Magnetic Field Non-destructive
Testing of Gantry Cranes. Materials, 12 (4), 564.
https://doi.org/10.3390/ma12040564
Juraszek, J. (2020). Fiber Bragg sensors on strain analysis
of power transmission lines. Materials, 13 (7), 1559.
https://doi.org/10.3390/ma13071559
Juraszek, J. & Antonik-Popiołek, P. (2021). Fibre optic
FBG sensors for monitoring of the temperature of the
building envelope. Materials, 14 (5), 1207. https://doi.
org/10.3390/ma14051207
Kong, Q., He, X., Cao, Y., Sun, Y., Chen, K. & Feng, J.
(2017). Numerical Analysis of the Dynamic Heat Transfer
through an External Wall under Different Outside
Temperatures. Energy Procedia, 105, 2818–2824.
Marino, B. M., Muńoz, N. & Thomas, L. P. (2018). Calculation
of the external surface temperature of a multi-layer
wall considering solar radiation effects. Energy & Buildings,
174, 452–463.
Świrska-Perkowska, J., Kucharczyk, A. & Wyrwał, J.
(2020). Energy Efficiency of a Solar Wall with Transparent
Insulation in Polish Climatic Conditions. Energies,
13 (4), 859. https://www.mdpi.com/1996-1073/13/4/859/
pdf
Yu, S., Cui, Y., Shao, Y. & Han, F. (2019). Simulation Research
on the Effect of Coupled Heat and Moisture
Transfer on the Energy Consumption and Indoor Environment
of Public Buildings. Energies, 12 (1), 141.
https://doi.org/10.3390/en12010141
10.22630/ASPA/2021.2.
Verification of determination of hydraulic conductivity for coarse soils by empirical formulas based on the density index
ORIGINAL_ARTICLE
83-92
2021
15
2
Krystyna
Jaśkiewicz
Tomasz
Godlewski
Chapuis, R. P. (2004). Predicting the saturated hydraulic
conductivity of sand and gravel using effective diameter
and void ratio. Canadian Geotechnical Journal, 41,
787–795.
Cheng, C. & Chen, X. (2007). Evaluation of Methods
for Determination of Hydraulic Properties in an Aquifer-
Aquitard System Hydrologically Connected to
River. Hydrogeology Journal, 15, 669–678. http://doi.
org/10.1007/s10040-006-0135-z
Devlin, J. F. (2015). HydrogeoSieveXL: an Excel-based
tool to estimate hydraulic conductivity from grain size
analysis. Hydrogeology Journal. http://doi.org/10.1007/
s10040-015-1255-0
Hazen, A. (1892). Some physical properties of sands and
gravels, with special reference to their use in filtration.
In 24th Annual Report of the State Board of Health of
Massachusetts (pp. 539–556). Boston: State Board of
Health of Massachusetts.
Head, K. & Epps, R. (2011). Manual of soil laboratory testing.
Vol. 2. Permeability, shear strength and compressibility
test. Dunbeath Mill: Whittles Publishing.
Hussain, F. & Nabi, G. (2016). Empirical Formulae Evaluation
for Hydraulic Conductivity Determination Based
on Grain Size Analysis. Pyrex Journal of Research in
Environmental Studies, 3 (3), 26–32.
Idris-Nda, A. (2013). Estimating Aquifer Hydraulic Properties
in Bida Basin, Central Nigeria Using Empirical
Methods. Earth Science Research, 2 (1). http://doi.
org/10.5539/esr.v2n1p209
Jiang, R., Li, T., Liu, D., Fu, Q., Hou, R., Li, Q., Cui, S.
& Li, M. (2021). Soil infiltration characteristics and
pore distribution under freezing-thawing conditions.
Cryosphere, 15 (4), 2133–2146. http://doi.org/10.5194/
tc-15-2133-2021
Kozeny, J. (1953). Das Wasser im Boden. Grundwasserbewegung.
In J. Kozeny (Ed.), Hydraulik (pp. 380–445).
Vienna: Springer.
Kozerski, B. (1977). Zasady obliczeń hydrogeologicznych
ujęć wód podziemnych. Wytyczne określania współczynnika
filtracji metodami pośrednimi i laboratoryjnymi.
Warszawa: Wydawnictwa Geologiczne.
Myślińska, E. (1998). Laboratoryjne badania gruntów.
Warszawa: Wydawnictwo Naukowe PWN.
Parylak, K., Zięba, Z., Bułdys, A. & Witek, K. (2013). Weryfikacja
wyznaczania współczynnika filtracji gruntów
niespoistych za pomocą wzorów empirycznych w ujęciu
ich mikrostruktury. Acta Sci. Pol. Architectura, 12 (2),
43–51.
Polski Komitet Normalizacyjny [PKN] (1986). Grunty budowlane.
Określenia symbole podział i opis gruntów
(PN-B-0248:1986). Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (1988). Grunty budowlane.
Badania próbek gruntu (PN-B-04481:1988).
Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2008). Badania
geotechniczne. Badania laboratoryjne gruntów. Część 4:
Oznaczanie składu granulometrycznego (PKN-CEN
ISO/TS 17892-4:2008). Warszawa: Polski Komitet Normalizacyjny.
Polski Komitet Normalizacyjny [PKN] (2019). Badania
geotechniczne. Oznaczanie i klasyfikowanie gruntów.
Część 2: Zasady klasyfikowania (PN-EN ISO 14688-2:
2019). Warszawa: Polski Komitet Normalizacyjny.
Shen, C., Zhu, J. & Gu, W. (2019). Prediction Method for
Hydraulic Conductivity considering the Effect of Sizes of Ellipsoid Soil Particles from the Microscopic Perspective.
Advances in Civil Engineering, 7213094. http://doi.
org/10.1155/2019/7213094
Twardowski, K. & Drożdżak, R. (2006). Pośrednie metody
oceny właściwości filtracyjnych gruntów. Wiertnictwo
Nafta Gaz, 23 (1), 477–486.
Twardowski, K. & Drożdżak, R. (2007). Uwarunkowania
dotyczące laboratoryjnych metod oznaczania wodoprzepuszczalności
gruntów. Wiertnictwo Nafta Gaz, 24 (1),
565–574.
Vukovic, M. & Soro, A. (1992). Determination of hydraulic
conductivity of porous media from grain-size composition
[trans. from Serbo-Croation by Dubravka Miladinov].
Littleton, CO: Water Resources Publications.
Wiłun, Z. (1982). Zarys geotechniki. Warszawa: Wydawnictwo
Komunikacji i Łączności.
Wrzesiński, G. (2020). Permeability coefficient tests in non-
-cohesive soils. Przegląd Naukowy. Inżynieria i Kształtowanie
Środowiska – Scientific Review. Engineering
and Environmental Sciences, 29 (1), 72–80. http://doi.
org/10.22630/PNIKS.2020.29.1.7
Zamarin, J. A. (1928). Raschet dvizheniya gruntovykh vod
[Calculation of ground-water flow]. Moskva: Izdatelstvo
I.V.Kh.
Zięba, Z. (2016). Influence of soil particle shape on saturated
hydraulic conductivity, Journal of Hydrology and
Hydromechanics, 65 (1), 80–87. http://doi.org/10.1515/
johh-2016-0054
Żurek, A. & Czudec, Ł. (2007). Pionowa zmienność prametrów
hydrogeologicznych w czwartorzędowym
zbior niku wód podziemnych (GZWP 450 – Dolina
rzeki Wisły) na przykładzie profilu studni badawczej
z poletka doświadczalnego AGH [The vertical variability
of the hydrogeological parameters in the quaternary
groundwater basin (MGWB 450 – the Vistula river valley)
illustrated by the example of the AGH University of
Science and Technology Experimental Field Research
Well Profile]. In A. Szczepański, E. Kmiecik & A. Żurek
(Eds.), Współczesne problemy hydrogeologii. Vol. 13.
Part 2 (pp. 389–399). Kraków: Wydział Geologii, Geofizyki
i Ochrony Środowiska AGH.
10.22630/ASPA/2021.2.
Problem of selection of suitable geosynthetics for the strengthening of subgrade in road construction, selection of assessment criteria
ORIGINAL_ARTICLE
93-101
2021
15
2
Elżbieta
Szafranko
Ajdukiewicz, J. (2004). Projektowanie z geosyntetykami
– możliwe zagrożenia dla projektantów – cz. I. Magazyn
Autostrady, 5, 84–90.
Bathurst, R. J. (2007). Geosynthetics Classification. IGS
Leaflets on Geosynthetics Applications. Austin, TX: IGS
Education Committee.
Bhatia, S. K., Smith, J. L. & Christopher, B. R. (1996). Geotextile
characterization and pore-size distribution: Part
III. Comparison of methods and application to design.
Geosynthetics International, 3 (3), 301–328.
Brózda, K. & Selejdak, J. (2019). The Functions of the
Geosynthetics in Roadway Applications. Acta Sci. Pol.
Architectura, 18 (2), 27–31. https://doi.org/10.22630/
ASPA.2019.18.2.19
Brózda, K., Selejdak, J. & Koteš, P. (2017). Analysis of
Properties of the FRP Rebar to Concrete Structures.
Applied Engineering Letters, 2 (1), 6–10. https://doi.
org/10.1016/j.proeng.2017.06.011
Bugajski, M. & Grabowski, W. (1999). Geosyntetyki w budownictwie
drogowym. Poznań: Wydawnictwo Politechniki
Poznańskiej.
Cristelo, N., Vieira, C. S. & Lurdes Lopes, M. de (2016).
Geotechnical and geoenvironmental assessment of
recycled construction and demolition waste for road
embankments. Procedia Engineering, 143, 51–58.
https://doi.org/10.1016/j.proeng.2016.06.007
Czarnecka, K. (2016). Geosyntetyki – przegląd materiałów
wzmacniających podłoże o słabych parametrach geotechnicznych
[Geosynthetics – a review of reinforcing
materials substrate with poor geotechnical parameters].
Archiwum Instytutu Inżynierii, 22, 93–104. https://doi.
org/10.21008/j.1897-4007.2016.22.07
Frost, J. D. & Lee, S. W. (2001). Microscale study of geomembrane-
geotextile interactions. Geosynthetics International,
8 (6), 577–597. https://doi.org/10.1680/
gein.8.0207
Gołoś, M. (2019). Funkcja stabilizacyjna geosyntetyków.
Geoinżynieria: Drogi, Mosty, Tunele, 4, 64–68.
Gradkowski, K. (2007). Geosyntetyki w budowie dróg zasady
stosowania geosyntetyków o n-tym kierunku wzmocnienia.
Inżynier Budownictwa, 7–8, 36–41.
Gradkowski, K. (2008). Efekt wzmocnień geotekstyliami
gruntowego podłoża nawierzchni dróg – badania doświadczalne.
Drogi i Mosty, 4, 5–22.
Gradkowski, K. & Żurawski, S. (2003). Budowle i roboty
ziemne. Warszawa: Oficyna Wydawnicza Politechniki
Warszawskiej.
Horodecki, G., & Duszyńska, A. (2017). Dobór geotekstyliów
i wyrobów pokrewnych pełniących funkcję zbrojenia
w budownictwie komunikacyjnym – wybrane problemy
inżynierskie [Selection of geotextiles and related
reinforcement products in transportation engineering
– selected engineering issues]. Magazyn Autostrady,
11–12, 42–46.
Huang, J., Han, J. & Oztoprak, S. (2009). Coupled mechanical
and hydraulic modeling of geosynthetic-reinforced
column-supported embankments. Journal of Geotechnical
and Geoenvironmental Engineering, 135 (8),
1011–1021.
Keller, G. R. (2016). Application of geosynthetics on lowvolume
roads. Transportation Geotechnics, 8, 119–131.
https://doi.org/10.1016/j.trgeo.2016.04.002
Koerner, G. R., Hsuan, Y. G. & Koerner, R. M. (2007). The
durability of geosynthetics. Chapter 3. In R. W. Sarsby
(Ed.), Geosynthetics in Civil Engineering (pp. 36–65).
Sawston, Cambs.: Woodhead Publishing.
Koerner, R. M. (2012). Designing with geosynthetics. Vol. 1.
6th ed. Bloomighton, IN: Xlibris.
Lawson, C. R. (2008). Geotextile containment for hydraulic
and environmental engineering. Geosynthetics International,
15 (6), 384–427. https://doi.org/10.1680/
gein.2008.15.6.384
Miszkowska, A. (2019). Funkcja filtracyjna geosyntetyków.
Geoinżynieria: Drogi, Mosty, Tunele, 2, 44–46.
Palmeira, E. M., Tatsuoka, F., Bathurst, R. J., Stevenson,
P. E. & Zornberg, J. G. (2008). Advances in Geosynthetics
Materials and Applications for Soil Reinforcement
and Environmental Protection Works. Electronic Journal
of Geotechnical Engineering, 13, 1–38.
Polski Komitet Normalizacyjny [PKN] (2015). Geosyntetyki.
Część 1: Terminy i defnicje (PN-EN ISO 10318-
1:2015). Warszawa: Polski Komitet Normalizacyjny.
Shukla, S. K. (2011). Handbook of Geosynthetic Engineering:
Geosynthetics and Their Applications. London: ICE
Publishing.
Sobolewski, J. (2010). Wymiarowanie zbrojeń geosyntetycznych
w konstrukcjach z gruntu zbrojonego zgodnie
z przepisami Eurokodu 7 [Design of geosynthetic reinforcements
for earth structures in line with regulations
of Eurocode 7]. Drogi i Mosty, 9 (2), 73–86.
Szafranko, E. (2013). Ocena ekspertów w analizach prowadzonych
metodą AHP przy wyborze wariantów inwestycji.
Inżynieria Morska i Geotechnika, 5, 400–404.
Szafranko, E. (2014a). Możliwości zastosowania geosyntetyków
do wzmacniania skarp w budownictwie drogowym.
Magazyn Autostrady, 3, 21–25.
Szafranko, E. (2014b). Metody analizy wariantów inwestycji
drogowych. Drogownictwo, 1, 18–25.
Szafranko, E. (2017). Decision problems in management of
construction projects. IOP Conference Series: Materials
Science and Engineering, 251 (1), 012048. https://doi.
org/10.1088/1757-899X/245/7/072026
Szczygielski, M. & Stopa, Ł. (2014). Usage of new soil
improvement techniques in road embankment constructions.
Technical Transactions Civil Engineering, 2-B (6),
109–116.
Szruba, M. (2014a). Geosyntetyki. Cz. 1. Charakterystyka
i funkcje według PN-EN ISO 10318:2007 [Geosynthetics
Materials. Part 1. Characteristics and functions
according to PN-EN ISO 10318:2007]. Nowoczesne Budownictwo
Inżynierne, 4, 48–51.
Szruba, M. (2014b). Geosyntetyki. Cz. 2. Zastosowanie
– podział według PN-EN ISO 10318:2007 [Geosynthetics.
Part 2. The application – classification according
PN-EN ISO 10318:2007]. Nowoczesne Budownictwo
Inżynierne, 5, 86–88.
Zornberg, J. G. (2017). Functions and Applications of Geosynthetics
in Roadways. Procedia Engineering, 189,
298–306. https://doi.org/10.1016/j.proeng.2017.05.048
10.22630/ASPA/2021.2.
Ecological material solutions with use of composites
ORIGINAL_ARTICLE
103-109
2021
15
2
Damian
Jończyk
Adamczyk, Z., Grzesik, B. & Harat, A. (2017). Środowiskowe
skutki stosowania żużla hutniczego jako składnika
kruszyw. Zeszyty Naukowe Politechniki Częstochowskiej.
Budownictwo, 23, 9–15. https://doi.org/10.17512/
znb.2017.1.01
Aly, M. (2012). Development of an Eco-friendly Composite
Material for Engineering Applications (PhD thesis).
Dublin City University, Dublin. http://doras.dcu.
ie/16857/1/Marwa_Aly__Final_thesis_for_printing.pdf
Badache, A., Benosman, A. S., Senhadji, Y. & Mouli, M.
(2018). Thermo-physical and mechanical characteristics
of sand-based lightweight composite mortars with
recycled high-density polyethylene (HDPE). Construction
and Building Materials, 163, 40–52. https://doi.
org/10.1016/j.conbuildmat.2017.12.069
Bobko, T. & Całusiński, P. (2012). Modelowanie racjonalnych
powiazań pomiędzy parametrami inżynierii procesowej
w produkcji energooszczędnych elementów budowlanych.
Zeszyty Naukowe Politechniki Częstochowskiej.
Budownictwo, 18, 13–27.
Brózda, K. (2015). Ekologiczne materiały kompozytowe
w budownictwie. In M. Ulewicz, J. Selejdak (Eds.),
Ekoinnowacje w materiałach i technologiach budowlanych
(pp. 60–69). Częstochowa: Wydawnictwo Wydziału
Zarządzania Politechniki Częstochowskiej.
Fraj, A. B. & Idir, R. (2017). Concrete based on recycled
aggregates – Recycling and environmental analysis:
A case study of Paris’ region. Construction and Building
Materials, 157, 952–964. https://doi.org/10.1016/j.conb
uildmat.2017.09.059
Góra, J. (2014). Możliwości zastosowania polskich kruszyw
węglanowych do betonów wysokowartościowych.
In S. Fic (Ed.), Materiały kompozytowe i możliwości
ich zastosowania w budownictwie tradycyjnym
i energooszczędnym (pp. 21–30). Lublin: Politechnika
Lubelska.
Han, J. & Thakur, J. K. (2014). Sustainable roadway construction
using recycled aggregates with geosynthetics.
Sustainable Cities and Society, 14, 342–350. https://doi.
org/10.1016/j.scs.2013.11.011
Hegde, A. (2017). Geocell reinforced foundation beds-past
findings , present trends and future prospects : A stateof-
the-art review. Construction and Building Materials,
154, 658–674. https://doi.org/10.1016/j.conbuildmat.20
17.07.230
Herrera, J. P., Bedoya-Ruiz, D. & Hurtado, J. E. (2018).
Seismic behavior of recycled plastic lumber walls:
An experimental and analytical research. Engineering
Structures, 177, 566–578. https://doi.org/10.1016/
j.engstruct.2018.10.006
Hollaway, L. C. (2003). The evolution of and the way forward
for advanced polymer composites in the civil infrastructure.
Construction and Building Materials, 17, 365–
378. https://doi.org/10.1016/S0950-0618(03)00038-2
Hung, K. C., Wu, T. L., Chen, Y. L., Wu, J. H. (2016). Assessing
the effect of wood acetylation on mechanical
properties and extended creep behavior of wood/recycled-
polypropylene composites. Construction and Building
Materials, 108, 139–145. https://doi.org/10.1016/j.c
onbuildmat.2016.01.039
Jacob-Vaillancourt, C. & Sorelli, L. (2018). Characterization
of concrete composites with recycled plastic aggregates
from postconsumer material streams. Construction
and Building Materials, 182, 561–572. https://doi.
org/10.1016/j.conbuildmat.2018.06.083
Kendall, K. (2007). Building the future with FRP composites.
Reinforced Plastics, 5, 26–33.
Lila, M. K., Kumar, F., Sharma, S. (2013). Composites from
waste for civil engineering applications. i-manager’s
Journal on Material Science, 1 (3), 1–10.
Marthong, C., Sangma, A. S., Choudhury, S. A., Pyrbot,
R. N., Tron, S. L., Mawroh, L. & Bharti, G. S (2017).
Structural Behavior of Recycled Aggregate Concrete
Beam-Column Connection in Presence of Micro Concrete
at Joint Region. Structures, 11, 243–251. https://
doi.org/10.1016/j.istruc.2017.07.001
Moallemi Pour, S. & Alam, M. S. (2016). Investigation of
Compressive Bond Behavior of Steel Rebar Embedded
in Concrete With Partial Recycled Aggregate Replacement.
Structures, 7, 153–164. https://doi.org/10.1016/
j.istruc.2016.06.010
Niemiro, J. (2016). Analiza i wykorzystanie dźwiękochłonnych
właściwości granulatu gumowego pozyskanego
z recyklingu. Zeszyty Naukowe Politechniki Częstochowskiej.
Budownictwo, 22, 257–264. https://doi.
org/10.17512/znb.2016.1.25
Srivabut, C., Ratanawilai, T. & Hiziroglu, S. (2018). Effect
of nanoclay, talcum, and calcium carbonate as filler on
properties of composites manufactured from recycled
polypropylene and rubberwood fiber. Construction
and Building Materials, 162, 450–458. https://doi.
org/10.1016/j.conbuildmat.2017.12.048
Thakur, J. K., Han, J., Pokharel, S. K. & Parsons, R. L.
(2012). Performance of geocell-reinforced recycled asphalt
pavement (RAP) bases over weak subgrade under
cyclic plate loading. Geotextiles and Geomembranes, 35,
14–24. https://doi.org/10.1016/j.geotexmem.2012.06.004
Väntsi, O. & Kärki, T. (2014). Utilization of recycled mineral
wool as filler in wood-polypropylene composites.
Construction and Building Materials, 55, 220–226.
https://doi.org/10.1016/j.conbuildmat.2014.01.050
Vieira, C. S. & Pereira, P. M. (2015). Transportation Geotechnics
Damage induced by recycled Construction and
Demolition Wastes on the short-term tensile behaviour
of two geosynthetics. Transportation Geotechnics, 4,
64–75. https://doi.org/10.1016/j.trgeo.2015.07.002
Wang, Y., Chen, J. & Geng, Y. (2015). Testing and analysis
of axially loaded normal-strength recycled aggregate
concrete filled steel tubular stub columns. Engineering
Structures, 86, 192–212. https://doi.org/10.1016/
j.engstruct.2015.01.007
Xu, J. J., Chen, Z. P., Xiao, Y., Demartino, C. & Wang, J. H.
(2017). Recycled Aggregate Concrete in FRP-confined
columns: A review of experimental results. Composite
Structures, 174, 277–291. https://doi.org/10.1016/
j.compstruct.2017.04.034
Younis, A., Ebead, U. & Judd, S. (2018). Life cycle cost
analysis of structural concrete using seawater, recycled
concrete aggregate, and GFRP reinforcement. Construction
and Building Materials, 175, 152–160. https://doi.
org/10.1016/j.conbuildmat.2018.04.183
10.22630/ASPA/2021.2.