Principles of Designing Water Elements in Urban Public Spaces
Abstract
:1. Introduction
1.1. Main Theses
- When designing water elements in the public space of large cities, functional, compositional, infrastructural and environmental aspects are taken into account;
- Water elements designed in public space can take various forms, which can be classified;
- The elements of water in public spaces contribute to well-being and are good for the general well-being of people, especially when the temperatures are high;
- Such solutions in public spaces definitely increase their social and aesthetic values;
- The installation of water devices in the city is very important for the physiologically equivalent temperature, which improves the heat feeling and human comfort;
- Appropriate design of the water element may influence the cooling effect in its immediate vicinity.
1.2. Objectives
- Development of a typology of water elements in hardscaped public spaces of large European, North American and Australian cities;
- Identification of the value that different types of water elements bring to urban spaces in selected examples;
- Recommendations for the introduction of water objects in the public spaces of large European cities.
2. Materials and Methods
- Landezine—projects in the “Squares and Plazas” category—from 2009 to 2021 (as of 16 November 2021)—a total of 301.
- ArchDaily—projects from the square category—a total of 117.
- PublicSpace.org (finalists and winners of the European Prize for Urban Public Space organized biannually by the Center of Contemporary Culture of Barcelona)—applications from 2000–2020, total number 357.
- Relaxing—a dominant influence on the sense of pleasure, related to stimulating reflection and peace, individual activities and activities requiring a high degree of privacy—with the features of restoration spaces;
- Spectacular—dominant influence on the sense of interest—associated with the possibility of intensive observation of the water system;
- Entertaining—dominant influence on commitment (robustness/responsiveness);
- Environmental—the dominant environmental function (Blue-Green Infrastructure functions).
- -
- Exchange value—moderate effect on increasing the commercial value of adjacent properties, in cases where it is an internal economic impact (return on investment);
- -
- Use value—moderate positive—the potential to provide moderately engaging activities (observing, a short game, etc.), significant—the potential to provide engaging activities (longer fun, age groups of users);
- -
- Image value—moderately positive—high potential to create a characteristic point crystallizing the mental map, significant—additionally high potential of a unique composition on a metropolitan and global scale;
- -
- Social value—moderate positive—the potential of the so-called integration—enabling the establishment of permanent or temporary social relationships (neighborly, intercultural, etc.), usually through the participation of a significant number of users (>15) in engaging and enjoyable activities, including those based on play;
- -
- Environmental value—moderately positive—limited in scale ecosystem services, including primarily maintenance (groundwater supply) and regulation (mitigation of rainwater runoff);
- -
- Cultural value—moderate positive—the presence of symbolism, meaning embedded in culture, significant positive—additionally maintaining formal and informal cultural practices;
- -
- Health value—moderate positive—the presence of a set of restorative place factors in the urban context—multisensory action (at least 2 senses—visual, auditory, tactile, etc.).
3. Results
3.1. Characteristics and Typology of Water Objects in Hardscaped Public Spaces
3.2. Limitations
4. Discussion
5. Conclusions
- 1.
- All recognized morphological types of water features in public spaces increase the value of these places. The role of water elements in public spaces can perform multiple functions, from purely aesthetic to fully functional, improving the well-being of people. The main conclusion of the study is the great positive importance of the presence of water-related design solutions in these types of spaces. The study shows that they increase the value of publicly accessible places in various aspects. None of the above-mentioned solutions was sterile and did not bring any additional significance; the mere existence of these objects increased the value of the described places. Hence the basic recommendation resulting from the study is that water elements should be designed in public spaces because they significantly increase the value of these places.
- 2.
- Water elements in public spaces should be designed in such a way that the pro-environmental profit is combined with the aesthetics and composition of the element to the specificity of the place. The presented research shows the correlation of these objects with the user, which builds an additional value system in public spaces. The distribution of these values is interesting, especially with regard to issues related to the exchange of services, aesthetics and environmental profit. The results of the study showed that what brings the effects of increasing biodiversity and is generally a pro-environmental action does not necessarily maximize the image value of a place (visual preference, etc.). The quoted conclusion indicates that when designing water elements in public spaces, the composition issues should be at least as important as ecological activities.
- 3.
- Water elements in public spaces can improve the physiological well-being of users when properly designed. Another recommendation related to the design of water elements in public spaces is their high socio-functional value related to the improvement of people’s well-being. It is especially visible in highly urbanized spaces and in places with higher temperature amplitudes. The use of such solutions significantly affects the aspects related to the well-being of users, despite the conclusive lack of significant cooling effects, while maintaining the biometeorological significance through the very awareness of the existence of water elements in the space positively influencing the perception of such places. By creating thermal comfort in the city, it will support the assets of pedestrians, tourists, cyclists, etc., and can lead to the encouragement of the population to spend more time outdoors and on the streets. This can be beneficial for cities in terms of tourism, socially, economically and environmentally.
- 4.
- Water elements enrich the composition of public spaces. Properly designed, they improve the key features of public space, such as imaging, vitality, mobility, solidity and comfort. These types of objects, properly designed and located taking into account the wider spatial context in a given place, causes that the values of this place are automatically higher. It should be remembered that the use, image and social and cultural values of urban water features largely depend on their type, size, structure, location and surroundings.
- 5.
- Water features contribute to the identification of places in cities. This type of element causes them to become pedestrian attractors, serving as characteristic points or landmarks depending on the visual impact and size. Consequently, they significantly increase the diversity of the city’s spatial structure, which in turn affects the orientation and consequent ease of movement around it.
- 6.
- Water components in public spaces should be designed to be part of the urban resilience system. The design of such facilities should be linked to a broader policy on the environmental footprint and quality of the city’s blue and green infrastructure. Properly selected types of pro-environmental values brought by such solutions should be particularly taken into account in projects located in spaces of dense historic urban tissue, or in other highly urbanized places. Last but not least, it is necessary to take into account the quantity and quality of water used in the design.
- 7.
- Water elements in public spaces should be designed in a holistic manner. In order to maximize the use value of the water element, its design should take into account: all possible uses (safety), interactions (weather) and legibility of the intended uses (affordances). It should also be aesthetic, adapted to the existing spatial context and, as far as possible, fulfill cultural functions. It does not change the fact that, as far as possible, these facilities should be designed to fulfill as many pro-environmental and social functions as possible.
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Exchange Value (Can Be Traded) | Use Value (Activities) | Image Value (Identity, Meaning, Good or Bad) | Social Value (Supports or Undermines Social Relations) | Environmental Value (Supports or Undermines Environmental Resources) | Cultural Value (Has Cultural Significance) | Health Value | |
---|---|---|---|---|---|---|---|
basin fountain | (+) | + | (+) | (+) | (−) | (+) | (+) |
cascade fountain | (+) | (+) | + | (+) | (−) | (+) | (+) |
pavement fountain | (+) | ++ | (+) | (+/++) | (−) | (+) | (+) |
urban trickle | (+) | + | (+) | (+) | (−) | (+) | |
reflective pool | (+) | (+) | + | (+) | (−) | (+) | (+) |
mist fountain | (+) | ++ | (+/++) | (+) | (−) | (+) | |
screen (2d, 3d) | (+) | ++ | ++ | (+) | (−) | (+) | |
swimming pool | (+) | ++ | (+) | (+) | (−) | (+) | (+) |
water square | (+) | + | (+) | (+) | + | (+) | |
semi-natural pond | (+) | + | (+) | (+) | ++ | (+) | (+) |
percolation trench | (+) | (+) | (+) | +/++ | (+) | (+) |
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Langie, K.; Rybak-Niedziółka, K.; Hubačíková, V. Principles of Designing Water Elements in Urban Public Spaces. Sustainability 2022, 14, 6877. https://doi.org/10.3390/su14116877
Langie K, Rybak-Niedziółka K, Hubačíková V. Principles of Designing Water Elements in Urban Public Spaces. Sustainability. 2022; 14(11):6877. https://doi.org/10.3390/su14116877
Chicago/Turabian StyleLangie, Karol, Kinga Rybak-Niedziółka, and Věra Hubačíková. 2022. "Principles of Designing Water Elements in Urban Public Spaces" Sustainability 14, no. 11: 6877. https://doi.org/10.3390/su14116877
APA StyleLangie, K., Rybak-Niedziółka, K., & Hubačíková, V. (2022). Principles of Designing Water Elements in Urban Public Spaces. Sustainability, 14(11), 6877. https://doi.org/10.3390/su14116877